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B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 1
SRM INSTITUTE OF SCIENCE & TECHNOLOGY
Kattankulathur, Kancheepuram 603203, Tamil Nadu, India
B. Tech in Electronics and Communication Engineering (with Specialization in Cyber Physical System)
(a) Mission of the Department
Mission Stmt - 1 Build an educational process that is well suited to local needs as well as satisfies the national and international accreditation requirements
Mission Stmt – 2 Attract the qualified professionals and retain them by building an environment that fosters work freedom and empowerment.
Mission Stmt - 3 With the right talent pool, create knowledge and disseminate, get involved in collaborative research with reputed universities, and produce competent graduands.
(b) Program Educational Objectives (PEO) The Program Educational Objectives for the Electronics and Communication Engineering program describe accomplishments that graduates are expected to attain within a few years of graduation.
PEO – 1 Establish themselves as successful and creative practicing professional engineers, both nationally and globally, in the related fields of Electronics and Communication Engineering.
PEO – 2 Apply the acquired knowledge and skills in solving real-world engineering problems; develop novel technology and design products which are economically feasible and socially relevant.
PEO – 3 Develop an attitude of lifelong learning for sustained career advancement and adapt to the changing multidisciplinary profession.
PEO – 4 Demonstrate leadership qualities, effective communication skills, and to work in a team of enterprising people in the multidisciplinary and multicultural environment with strong adherence to professional ethics.
(c) Mission of the Department to Program Educational Objectives (PEO) Mapping
Mission Stmt. - 1 Mission Stmt. - 2 Mission Stmt. – 3
PEO - 1 H H H
PEO - 2 L M H PEO - 3 M L H PEO - 4 H H H
H – High Correlation, M – Medium Correlation, L – Low Correlation
(d) Mapping Program Educational Objectives (PEO) to Program Learning Outcomes (PLO) Program Learning Outcomes (PLO)
Graduate Attributes (GA) Program Specific Outcomes (PSO)
Eng
inee
ring
Kno
wle
dge
Pro
blem
Ana
lysi
s
Des
ign
&
Dev
elop
men
t
Ana
lysi
s, D
esig
n,
Res
earc
h
Mod
ern
Too
l Usa
ge
Soc
iety
& C
ultu
re
Env
ironm
ent &
S
usta
inab
ility
Eth
ics
Indi
vidu
al &
Tea
m
Wor
k
Com
mun
icat
ion
Pro
ject
Mgt
. &
Fin
ance
Life
Lon
g Le
arni
ng
Des
ign,
Pro
toty
pe
and
Tes
t Mod
ern
EC
E S
yste
ms
Pro
ject
Man
agem
ent
Tec
hniq
ues
Impl
emen
t EC
E
Sys
tem
s
PEO - 1 M H M H H H M
PEO - 2 H H H H H H M L H H L H
PEO - 3 M H M H L PEO - 4 H H H H H H L
H – High Correlation, M – Medium Correlation, L – Low Correlation Program Specific Outcomes (PSO) Graduates of baccalaureate degree program in ECE must demonstrate knowledge and hands-on competence in the ability to:
PSO – 1 Analyze and verify the correctness of CPS implementations against system requirements and timing constraints. PSO – 2 Design CPS requirements based on operating system and hardware architecture constraints.
PSO – 3 Implement specific software CPS using existing synthesis tools and analyze the functional behavior of CPS based on standard modeling formalisms.
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 2
(e) Program Structure for B.Tech in Electronics and Communication Engineering with Specialization in Cyber Physical System
1. Humanities & Social Sciences including Management Courses (H)
Course Course Hours/ Week
Code Title L T P C 18LEH101J English 2 0 2 3
18LEH102J Chinese
18LEH103J French
18LEH104J German 2 0 2 3 18LEH105J Japanese
18LEH106J Korean
18PDH101L General Aptitude 0 0 2 1
18PDH102T Management Principles for Engineers 2 0 0 2
18PDH103J Social Engineering 1 0 2 2 18PDH201L Employability Skills & Practices 0 0 2 1
Total Learning Credits 12
2. Basic Science Courses (B)
Course Course Hours/ Week
Code Title L T P C
18PYB101J Physics: Electromagnetic Theory, Quantum Mechanics, Waves and Optics
3 1 2 5
18CYB101J Chemistry 3 1 2 5 18MAB101T Calculus and Linear Algebra 3 1 0 4
18MAB102T Advanced Calculus and Complex Analysis 3 1 0 4
18MAB201T Transforms and Boundary Value Problems 3 1 0 4
18MAB203T Probability and Stochastic Process 3 1 0 4
18MAB302T Discrete Mathematics for Engineers 3 1 0 4 18BTB101T Biology 2 0 0 2
Total Learning Credits 32
3. Engineering Science Courses (S)
Course Course Hours/ Week
Code Title L T P C
18MES101L Engineering Graphics and Design 1 0 4 3
18EES101J Basic Electrical and Electronics Engineering 3 1 2 5
18MES103L Civil and Mechanical Engineering Workshop 1 0 4 3 18CSS101J Programming for Problem Solving 3 0 4 5
18ECS201T Control Systems 3 0 0 3
Total Learning Credits 19
4. Professional Core Courses (C)
Course Course Hours/ Week
Code Title L T P C
18ECC102J Electronic Devices 3 0 2 4
18ECC103J Digital Electronic Principles 3 0 2 4
18ECC104T Signals and Systems 3 1 0 4 18ECC105T Electromagnetics and Transmission Lines 3 0 0 3
18ECC201J Analog Electronic Circuits 3 0 2 4
18ECC202J Linear Integrated Circuits 3 0 2 4
18ECC203J Microprocessor, Microcontroller and Interfacing Techniques
3 0 2 4
18ECC204J Digital Signal Processing 3 0 2 4
18ECC205J Analog and Digital Communication 3 0 2 4
18ECC206J VLSI Design 3 0 2 4
18ECC301T Wireless Communications 3 1 0 4 18ECC302J Microwave & Optical Communications 3 0 2 4
18ECC303J Computer Communication Networks 3 0 2 4
18ECC350T Comprehension 0 1 0 1
Total Learning Credits 52
5. Professional Elective Courses (E)
Course Course Hours/ Week
Code Title L T P C
Professional Elective – 1 3 0 0 3
Professional Elective – 2 3 0 0 3 Professional Elective – 3 3 0 0 3
Professional Elective – 4 3 0 0 3
Professional Elective – 5 3 0 0 3
Professional Elective – 6 3 0 0 3
Total Learning Credits 18
6. Open Elective Courses (O)
Course Course Hours/ Week
Code Title L T P C
Open Elective – 1 3 0 0 3
Open Elective – 2 3 0 0 3 Open Elective – 3 3 0 0 3
Open Elective – 4 3 0 0 3
Total Learning Credits 12
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 3
7. Project Work, Seminar, Internship In Industry / Higher Technical Institutions (P)
Course Course Hours/ Week
Code Title L T P C
18ECP101L Massive Open Online Course- I
18ECP102L Industrial Training - I 0 0 2 1
18ECP103L Seminar – I
18ECP104L Massive Open Online Course- II
18ECP105L Industrial Training - II 0 0 2 1
18ECP106L Seminar – II
18ECP107L Minor Project 0 0 6 3
18ECP108L Internship (4-6 weeks)
18ECP109L Project 0 0 20 10
18ECP110L Semester Internship
Total Learning Credits 15
8. Mandatory Courses (M)
Course Course Hours/ Week
Code Title L T P C 18PDM101L Professional Skills and Practices 0 0 2 0
18PDM201L Competencies in Social Skills 0 0 2 0
18PDM203L Entrepreneurial Skill Development
18PDM202L Critical and Creative Thinking Skills 0 0 2 0
18PDM204L Business Basics for Entrepreneurs 18PDM301L Analytical and Logical Thinking Skills
0 0 2 0 19PDM302L Entrepreneurship Management
18LEM101T Constitution of India 1 0 0 0
18LEM102J Value Education 1 0 1 0
18GNM101L Physical and Mental Health using Yoga 0 0 2 0 18GNM102L NSS
0 0 2 0 18GNM103L NCC
18GNM104L NSO
18LEM109T Indian Traditional Knowledge 1 0 0 0
18LEM110L Indian Art Form 0 0 2 0
18CYM101T Environmental Science 1 0 0 0
Total Learning Credits -
List of Professional Elective Courses (E) Any 6 Courses
Course Course Hours/ Week
Code Title L T P C
18ECE250T Principles of Cyber Physical System 3 0 0 3
18ECE251T Embedded and Implanted Devices for Cyber Physical System
3 0 0 3
18ECE252T Sensors and Actuators for Cyber Physical System
3 0 0 3
18ECE253T Unsupervised Intelligence in Cyber Physical System
3 0 0 3
18ECE254T Real Time Cyber Physical System 3 0 0 3
18ECE350T Cyber Physical Interface and Automation 3 0 3 3
18ECE351T High Performance Computing for Cyber Physical System
3 0 0 3
18ECE352T Cyber Physical Control System 3 0 0 3
18ECE353T Cyber Security 3 0 3 3
18ECE354T Cloud and Distributed Systems for Cyber Physical System
3 0 0 3
18ECE355T Design of Cyber Physical System 3 0 0 3
18ECE356T Mobile Cyber Physical System 3 0 0 3
List of Open Elective Courses (O) Any 4 Courses
Course Course Hours/ Week
Code Title L T P C
18ECO101T Short-Range Wireless Communication 3 0 0 3 18ECO102J Electronic Circuits & Systems 2 0 2 3
18ECO103T Modern Wireless Communication Systems 3 0 0 3
18ECO104J Audio and Speech Processing 2 0 2 3
18ECO105T Underwater Acoustics 3 0 0 3
18ECO106J PCB Design and Manufacturing 2 0 2 3 18ECO107T Fiber Optics and Optoelectronics 3 0 0 3
18ECO108J Embedded System Design using Arduino 2 0 2 3
18ECO109J Embedded System Design using Raspberry Pi
2 0 2 3
18ECO110J 3D Printing Hardware and Software 2 0 2 3
18ECO131J Virtual Instrumentation 2 0 2 3
18ECO132T Analytical Instrumentation 3 0 0 3
18ECO133T Sensors and Transducers 3 0 0 3
18ECO134T Industrial Automation 3 0 0 3 18ECO135T Fundamentals of MEMS 3 0 0 3
18ECO121T Basics of Biomedical Engineering 3 0 0 3
18ECO122T Hospital Information Systems 3 0 0 3
18ECO123T Biomedical Imaging 3 0 0 3
18ECO124T Human Assist Devices 3 0 0 3 18ECO125T Quality Control for Biomedical Devices 3 0 0 3
18ECO126T Sports Biomechanics 3 0 0 3
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 4
(f) Program Articulation for B.Tech in Electronics and Communication Engineering with Specialization in Cyber Physical System
Program Learning Outcomes (PLO)
Graduate Attributes PSO
Course Code
Course Name
Eng
inee
ring
Kno
wle
dge
Pro
blem
Ana
lysi
s
Des
ign
& D
evel
opm
ent
Ana
lysi
s, D
esig
n,
Res
earc
h
Mod
ern
Too
l Usa
ge
Soc
iety
& C
ultu
re
Env
ironm
ent &
S
usta
inab
ility
Eth
ics
Indi
vidu
al &
Tea
m W
ork
Com
mun
icat
ion
Pro
ject
Mgt
. & F
inan
ce
Life
Lon
g Le
arni
ng
PS
O-1
PS
O-2
PS
O-3
18ECS201T Control Systems H H - - - - - - - - - - H - -
18ECC102J Electronic Devices H - - H - - L H M - M L L -
18ECC103J Digital Electronic Principles H M H - H - - - H - - - M - L
18ECC104T Signals and Systems H H M M M - - - - - - - L - L
18ECC105T Electromagnetics and Transmission Lines M H - - - - - - - - L - M
18ECC201J Analog Electronic Circuits L M H - M - - - M - - M H L
18ECC202J Linear Integrated Circuits H M H - M - - - M - - - H L H
18ECC203J Microprocessor, Microcontroller and Interfacing Techniques M M M - H - - - - H - H L - M
18ECC204J Digital Signal Processing H M H - - - - - - - - - M - H
18ECC205J Analog and Digital Communication M H H M H - - - H H - M H M H
18ECC206J VLSI Design H M M - H - - - H M L M - - M
18ECC301T Wireless Communication H H H H M - - - - M - M M - H
18ECC302J Microwave & Optical Communications H H H M - - - - - - - - M - M
18ECC303J Computer Communication Networks - - M - L L M - - - - M - - H
18ECC350T Comprehension H H M L L L L L L L L L M M M
18ECP101L/ 18ECP104L
Massive Open Online Course-I/II - - - - - M L - - H - H - M -
18ECP102L/ 18ECP105L
Industrial Training-I/II H M M M M L M H H M H M L L L
18ECP103L/ 18ECP106L
Seminar-I/II - M M H - M H - - H - M - - -
18ECP107L/ 18ECP108L
Minor Project / Internship (4-6 weeks) H H H H M M H M M M M L M M M
18ECP109L/ 18ECP110L
Project / Semester Internship H H H H H H H H H H H H H H H
18ECE250T Principles of Cyber Physical System H M H M L L M - - - - - - - H
18ECE251T Embedded and Implanted Devices for Cyber Physical System H - - H H - - M - H - L M L -
18ECE252T Sensors and Actuators for Cyber Physical System H - H M - - L - - - - - H - M
18ECE253T Unsupervised Intelligence in Cyber Physical System H M H - - - L M H - - - L L M
18ECE254T Real Time Cyber Physical System H M H - - - - M H - - - H L -
18ECE350T Cyber Physical Interface and Automation H M M - - - - - - - - - - - H
18ECE351T High Performance Computing for Cyber Physical System H - M H - - - - - - - - M - M
18ECE352T Cyber Physical Control System H M H H - - - - - - - - H L -
18ECE353T Cyber Security H M H H - - M - - M - - H L -
18ECE354T Cloud and Distributed Systems for Cyber Physical System H M H - H - - - - - - L H L -
18ECE355T Design of Cyber Physical System H - M - - H H L L - - M L L -
18ECE356T Mobile Cyber Physical System H - H - M - - - - M - - M - L
H – High Correlation, M – Medium Correlation, L – Low Correlation, PSO – Program Specific Outcomes (PSO)
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 5
(g) Implementation Plan for B.Tech in Electronics and Communication Engineering with Specialization in Cyber Physical System
Semester - I
Code Course Title Hours/ Week
C L T P
18LEH102J- 18LEH106J
Foreign Language (Chinese/ French/ German/ Japanese / Korean)
2 0 2 3
18MAB101T Calculus and Linear Algebra 3 1 0 4 18CYB101J Chemistry 3 1 2 5
18CSS101J Programming for Problem Solving 3 0 4 5
18MES103L Civil and Mechanical Engineering Workshop 1 0 4 3
18PDM101L Professional Skills and Practices 0 0 2 0
18LEM102J Value Education 1 0 1 0 18GNM102L NCC / NSS / NSO 0 0 2 0
Total Learning Credits 20
Semester – II
Code Course Title Hours/ Week
C L T P
18LEH101J English 2 0 2 3
18MAB102T Advanced Calculus and Complex Analysis 3 1 0 4
18PYB101J Physics: Electromagnetic Theory, Quantum Mechanics, Waves and Optics
3 1 2 5
18MES101L Engineering Graphics and Design 1 0 4 3
18EES101J Basic Electrical and Electronics Engineering 3 1 2 5
18PDH101L General Aptitude 0 0 2 1
18LEM101T Constitution of India 1 0 0 0 18GNM101L Physical and Mental Health using Yoga 0 0 2 0
Total Learning Credits 21
Semester - III
Code Course Title Hours/ Week
C L T P 18MAB201T Transforms and Boundary Value Problems 3 1 0 4
18ECS201T Control Systems 3 0 0 3 18ECC102J Electronic Devices 3 0 2 4
18ECC103J Digital Electronic Principles 3 0 2 4
18ECC104T Signals and Systems 3 1 0 4
18ECC105T Electromagnetics and Transmission Lines 3 0 0 3
18PDH103J Social Engineering 1 0 2 2 18PDM201L Competencies in Social Skills 0 0 2 0
18CYM101T Environmental Science 1 0 0 0
Total Learning Credits 24
Semester - IV
Code Course Title Hours/ Week
C L T P 18MAB203T Probability and Stochastic Process 3 1 0 4
18BTB101T Biology 2 0 0 2 18ECC201J Analog Electronic Circuits 3 0 2 4
18ECC202J Linear Integrated Circuits 3 0 2 4
Professional Elective-1 3 0 0 3
Open Elective-1 3 0 0 3
18PDH102T Management Principles for Engineers 2 0 0 2 18PDM202L Critical and Creative Thinking Skills 0 0 2 0
Total Learning Credits 22
Semester - V
Code Course Title Hours/ Week
C L T P
18MAB302T Discrete Mathematics for Engineers 3 1 0 4
18ECC203J Microprocessor, Microcontroller and Interfacing Techniques
3 0 2 4
18ECC204J Digital Signal Processing 3 0 2 4
18ECC205J Analog and Digital Communication 3 0 2 4 Professional Elective – 2 3 0 0 3
Open Elective – 2 3 0 0 3
18ECP101L/ 18ECP102L/ 18ECP103L
Massive Open Online Course-I / Industrial Training-I / Seminar-I
0 0 2 1
18PDM301L Analytical and Logical Thinking Skills 0 0 2 0
18LEM110L Indian Art Form 0 0 2 0
Total Learning Credits 23
Semester - VI
Code Course Title Hours/ Week
C L T P
18ECC206J VLSI Design 3 0 2 4 18ECC302J Microwave and Optical Communications 3 0 2 4
18ECC303J Computer Communication Networks 3 0 2 4
18ECC350T Comprehension 0 1 0 1
Professional Elective-3 3 0 0 3
Professional Elective-4 3 0 0 3 Open Elective-3 3 0 0 3
18ECP104L/ 18ECP105L/ 18ECP106L
Massive Open Online Course-II / Industrial Training-II / Seminar-II
0 0 2 1
18PDH201L Employability Skills and Practices 0 0 2 1
18LEM109T Indian Traditional Knowledge 1 0 0 0
Total Learning Credits 24
Semester - VII
Code Course Title Hours/ Week
C L T P
18ECC301T Wireless Communications 3 1 0 4
Professional Elective-5 3 0 0 3
Professional Elective-6 3 0 0 3
Open Elective-4 3 0 0 3
18ECP107L / 18ECP108L
Minor Project / Internship (4-6 weeks) 0 0 6 3
Total Learning Credits 16
Semester - VIII
Code Course Title Hours/ Week
C L T P
18ECP109L / 18ECP110L
Project / Semester Internship 0 0 20 10
Total Learning Credits 10
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 6
B. Tech in Electronics and Communication Engineering
(with Specialization in Cyber Physical System)
2018 Regulations
Engineering Science Courses (S)
Department of Electronics and Communication Engineering SRM Institute of Science and Technology
SRM Nagar, Kattankulathur – 603203, Kancheepuram District, Tamilnadu
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 7
Course Code
18ECS201T Course Name
CONTROL SYSTEMS Course
Category Professional Core
L T P C
3 0 0 3
Pre-requisite Courses
18MAB102T Co-requisite
Courses 18ECC104T
Progressive Courses
Nil
Course Offering Department Electronics and Communication Engineering Data Book / Codes/Standards Nil
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Learn about mathematical modeling techniques of mechanical and electrical systems 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 CLR-2 : Impart knowledge about the transient and steady state error and analysis
Leve
l of T
hink
ing
(Blo
om)
Exp
ecte
d P
rofic
ienc
y (%
)
Exp
ecte
d A
ttain
men
t (%
)
Eng
inee
ring
Kno
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dge
Pro
blem
Ana
lysi
s
Des
ign
& D
evel
opm
ent
Ana
lysi
s, D
esig
n, R
esea
rch
Mod
ern
Too
l Usa
ge
Soc
iety
& C
ultu
re
Env
ironm
ent &
Sus
tain
abili
ty
Eth
ics
Indi
vidu
al &
Tea
m W
ork
Com
mun
icat
ion
Pro
ject
Mgt
. & F
inan
ce
Life
Lon
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arni
ng
PS
O–1
: Pro
fess
iona
l
Ach
ieve
men
t P
SO
– 2
: Pro
ject
Man
agem
ent
Tec
hniq
ues
PS
O –
3: A
naly
ze &
Res
earc
h
CLR-3 : Identify and analyze stability of a system in time domain using root locus technique
CLR-4 : Know about different frequency domain analytical techniques
CLR-5 : Acquire the knowledge of a controller for specific applications
CLR-6 : Impart knowledge on controller tuning methods
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Determine Transfer function of a system by mathematical modeling, block diagram reduction and signal flow graphs 1,2 80 80 H H - - - - - - - - - - H - -
CLO-2 : Identify the standard test inputs, time domain specifications and calculate steady state error 1,2 85 80 H H - - - - - - - - - - H - -
CLO-3 : Plot a root locus curve and analyze the system stability using Routh array 2,3 90 85 H H - - - - - - - - - - H - -
CLO-4 : Analyze the frequency domain specifications from bode and polar plots 2,3 90 85 H H - - - - - - - - - - H - -
CLO-5 : Design a closed loop control system for specific application 1,2,3 80 80 H H - - - - - - - - - - H - -
CLO-6 : Identification of controller parameters and tuning 1,2,3 85 85 H H - - - - - - - - - - H - -
Duration (hour)
9 9 9 9 9
S-1
SLO-1 Open and closed loop control system Standard test signals and their expression Poles and zeros of a system Frequency domain analysis Controllers-Significance and Need
SLO-2 Feedback and Feed forward control systems Type number and order of a system Pole zero plot and concept of s plane Frequency domain specifications Stability of closed loop systems
S-2 SLO-1
Transfer function of a system and basis of Laplace transforms
Transfer function of First order system for Step and ramp signal
Proper, Strictly Proper and Improper systems
Frequency domain plots, minimum and non minimum phase systems
SISO and MIMO control systems
SLO-2 Need for mathematical modeling Transfer function of First order system Impulse and parabolic signal
Characteristic equation Correlation between time and frequency domain
Types of controllers-ON-OFF,P,I,D
S-3
SLO-1 Representation of mechanical translational systems using differential equation and determination of transfer function
General transfer function of second order system
Concept of stability from pole zero location
Bode plot approach and stability analysis
Composite Controller-PI,PD and PID
SLO-2 Identification of damping factor and classification based on it
Need for Stability analysis and available techniques
Rules for sketching bode plot Controller parameters and tuning methods
S-4 SLO-1
Representation of mechanical rotational systems and determination of transfer function
Step response of critically damped second order system
Necessary and sufficient Condition for stability
Bode plot of typical systems Design Specification, controller configurations- ON-OFF controller
SLO-2 Step response of under damped second order system
Significance of Routh Hurwitz Technique
S-5
SLO-1 Conversions of Mechanical system to Electrical system
Step response of over damped second order system
Computation of Routh array
Bode plot of typical systems Design Specification, controller configurations-PID controller
SLO-2 f-V and f-I electrical analogies Step response of undamped second order system
Routh array of stable systems
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 8
S-6 SLO-1
Block diagram reduction rules and methodology
Time domain specifications and their significance
Routh array of Unstable systems Polar plot and significance Design of speed control system for DC motor
SLO-2 Numerical solution Routh array of Unstable systems Nyquist stability criterion
S-7 SLO-1
Evaluation of transfer function using block diagram reduction
Transient and steady state error analysis Root locus technique Sketching of polar plot on polar graphs
Design of control system for Twin Rotor Multi input Multi output System(TRMS) with one degree of freedom SLO-2 Static and dynamic Error coefficients Rules for sketching root locus
S-8 SLO-1
Signal flow graphs and evaluation of transfer function
Static error constants and evaluation of steady state error
Root locus plot of typical systems Polar plot of typical systems Case study 1 SLO-2
S-9 SLO-1
Block diagram to signal flow conversion Dynamic error constants and evaluation of steady state error
Root locus plot of typical systems Polar plot of typical systems Case study 2 SLO-2
Learning Resources
1. Nagrath.J and Gopal.M,, “Control System Engineering”, 5th Edition, New Age, 2007 2. Benjamin C Kuo, “Automatic Control System”, 9th edition, John Wiley & Sons, 2010
3. Gopal.M, “Control System Principles and Design”, 2nd Edition, TMH, 2002 4. Sivanandam and Deepa, “Control system Engineering using MATLAB”, 2nd edition, Vikas publishers, 2007
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)
Level 1 Remember
40% 30% 30% 30% 30% Understand
Level 2 Apply
40% 40% 40% 40% 40% Analyze
Level 3 Evaluate
20% 30% 30% 30% 30% Create
Total 100 % 100 % 100 % 100 % 100 %
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers
Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Mr. Anuj Kumar, Bombardier Transportation, Ahmedabad, [email protected] 1. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] Dr. T. Deepa, SRMIST
2. Mr. Hariharasudhan - Johnson Controls, Pune, [email protected] 2. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected] Mrs. R. Bakhya Lakshmi, SRMIST
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 9
B. Tech in Electronics and Communication Engineering (with specialization in Cyber Physical System)
2018 Regulations
Professional Core Courses (C)
Department of Electronics and Communication Engineering SRM Institute of Science and Technology
SRM Nagar, Kattankulathur – 603203, Kancheepuram District, Tamilnadu
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 10
Course Code
18ECC102J Course Name
ELECTRONIC DEVICES Course
Category C Professional Core
L T P C
3 0 2 4
Pre-requisite Courses
18EES101J Co-requisite
Courses Nil
Progressive Courses
18ECC201J, 18ECC202J, 18ECE203T, 18ECE303T, 18ECE321T, 18ECE322T
Course Offering Department Electronics and Communication Engineering Data Book / Codes/Standards Nil
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Provide a basis for understanding semiconductor material, how a pn junction is formed and its principle of operation 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
CLR-2 : Explain the importance of diode in electronic circuits by presenting appropriate diode applications
Leve
l of T
hink
ing
(Blo
om)
Exp
ecte
d P
rofic
ienc
y (%
)
Exp
ecte
d A
ttain
men
t (%
)
Eng
inee
ring
Kno
wle
dge
Pro
blem
Ana
lysi
s
Des
ign
& D
evel
opm
ent
Ana
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s, D
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n, R
esea
rch
Mod
ern
Too
l Usa
ge
Soc
iety
& C
ultu
re
Env
ironm
ent &
Sus
tain
abili
ty
Eth
ics
Indi
vidu
al &
Tea
m W
ork
Com
mun
icat
ion
Pro
ject
Mgt
. & F
inan
ce
Life
Lon
g Le
arni
ng
PS
O–1
: Pro
fess
iona
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men
t
PS
O –
2: P
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3: A
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Res
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h CLR-3 : Discuss the basic characteristics of several other types of diodes that are designed for specific applications
CLR-4 : Describe the basic structure, operation and characteristics of BJT, and discuss its use as a switch and an amplifier.
CLR-5 : Describe the basic structure, operation and characteristics of MOSFET, and discuss its use as a switch and an amplifier.
CLR-6 : Use modern engineering tools such as PSPICE to carry out design experiments and gain experience with instruments and methods used by technicians and electronic engineers
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Explain the operation, characteristics, parameters and specifications of semiconductor diodes and special diodes 1 60 70 H - - - - - - - - - - M - - -
CLO-2 : Illustrate important applications of semiconductor diodes and special diodes. 2 60 70 - - - - - - - - - - - M - - -
CLO-3 : Review bipolar transistor construction, operation, characteristics and parameters, as well as its application in amplification and switching.
1 60 70 H - - - - - - - - - - M - - -
CLO-4 : Review field-effect transistor construction, operation, characteristics and parameters, as well as its application in amplification and switching.
1 60 70 H - - - - - - - - - - M - L -
CLO-5 : Construct a circuit, then make functional measurements to understand the operating characteristics of the device / circuit. 3 70 75 - - - - H - - - - - - - L L -
CLO-6 : Solve specific design problem, which after completion will be verified using modern engineering tools such as PSPICE. 2 70 75 - - - - H - - L H M - M - - -
Duration (hour)
Semiconductor Diodes Diode Circuits Special Diodes Bipolar Junction Transistors MOS Field-Effect Transistors
15 15 15 15 15
S-1 SLO-1
Basic semiconductor theory: Intrinsic & extrinsic semiconductors
HWR operation, Efficiency and ripple factor Backward diode Physical structure Physical structure
SLO-2 Current flow in semiconductors Problem solving Varactor diode Device operation of BJT Device operation of E-MOSFET & D-MOSFET
S-2 SLO-1 PN junction theory: Equilibrium PN junction
Center-Tapped Transformer FWR operation, Efficiency and ripple factor
Step recovery diode Current-Voltage characteristics of CE BJT configuration
I-V characteristics of E-MOSFET
SLO-2 Forward biased PN junction Problem solving Point-contact diode Current-Voltage characteristics of CE BJT configuration
Problem solving
S-3 SLO-1 Reverse biased PN junction
Bridge FWR operation, Efficiency and ripple factor
Metal-semiconductor junction: Structure, Energy band diagram
Current-Voltage characteristics of CB BJT configuration
Derive drain current
SLO-2 Relation between Current and Voltage Problem solving Forward & Reverse Characteristics of Schottky Diode
Current-Voltage characteristics of CB BJT configuration
Problem solving
S 4-5
SLO-1 Lab 1: PN Junction Diode Characteristics Lab 4: Diode clipping and clamping circuits Lab 7: Series and Shunt Regulators
Lab 10: BJT and MOSFET Switching Circuits
Lab 13: Repeat Experiments SLO-2
S-6 SLO-1 Calculate depletion width Filters: Inductor & Capacitor Filters Tunnel Diode
Current-Voltage characteristics of CC BJT configuration
Derive transconductance
SLO-2 Calculate barrier potential Problem solving Tunnel Diode Current-Voltage characteristics of CC BJT configuration
Problem solving
S-7 SLO-1 Derive diode current equation Filters: LC & CLC Filters Gunn Diode BJT as an amplifier CMOS FET
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 11
SLO-2 Derive diode current equation Problem solving Gunn Diode BJT as a switch MOSFET as an amplifier
S-8 SLO-1
Effect of Capacitance in PN junction: Transition Capacitance
Diode Clippers IMPATT Diode BJT circuit models – h-parameter MOSFET as a switch
SLO-2 Diffusion Capacitance Problem solving IMPATT Diode BJT circuit models – hybrid-π parameter Problem solving
S 9-10
SLO-1 Lab 2: Zener diode characteristics Lab 5: BJT Characteristics Lab 8: MOSFET Characteristics
Lab 11: Photoconductive Cell, LED, and Solar Cell Characteristics
Lab-14: Model Examination SLO-2
S-11 SLO-1
Energy band structure of PN Junction Diode
Diode Clampers PIN Diode BJT biasing circuits and stability analysis: Base bias and emitter bias
Biasing Circuits for MOSFET: Gate Bias
SLO-2 Ideal diode and its current-voltage characteristics
Problem solving PIN Photodiode Problem solving Problem Solving
S-12 SLO-1 Terminal characteristics & parameters Voltage Multipliers Avalanche photodiode Voltage-divider bias Self-bias
SLO-2 Diode modeling Zener diode: Characteristics, breakdown mechanisms
Laser diode Problem solving Problem Solving
S-13 SLO-1 DC load line and analysis
Zener resistances and temperature effects Zener diode as voltage regulator
Problem solving Collector-feedback bias Voltage-divider bias
SLO-2 Problem solving Problem solving Problem solving Problem solving Problem Solving
S 14-15
SLO-1 Lab 3: Diode rectifier circuits Lab 6: BJT Biasing Circuits Lab 9: MOSFET Biasing Circuits
Lab 12: Simulation experiments using PSPICE
Lab 15: End-Semester Practical Examination SLO-2
Learning Resources
1. David A. Bell, Electronic Devices and Circuits, 5th ed., Oxford University Press, 2015 2. Donald Neamen, Electronic Circuits: Analysis and Design, 3rd ed., McGraw-Hill Education, 2011 3. Adel S. Sedra, Kenneth C. Smith, Microelectronic Circuits: Theory and Applications, OUP, 2014 4. Thomas L. Floyd, Electronic Devices”, 9th ed., Pearson Education, 2013
5. Robert L. Boylestad, Louis Nashelsky, Electronic Devices and Circuit Theory, 11th ed., Pearson Education, 2013 6. Muhammad Rashid, Microelectronic Circuits: Analysis & Design, 2nd ed., Cengage Learning, 2010 7. Muhammed H Rashid, Introduction to Pspice using OrCAD for circuits and electronics, 3rd ed., Pearson, 2004 8. Laboratory Manual, Department of ECE, SRM University
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)#
Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
20% 20% 15% 15% 15% 15% 15% 15% 15% 15% Understand
Level 2 Apply
20% 20% 20% 20% 20% 20% 20% 20% 20% 20% Analyze
Level 3 Evaluate
10% 10% 15% 15% 15% 15% 15% 15% 15% 15% Create
Total 100 % 100 % 100 % 100 % - # CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Mr. Anuj Kumar, Bombardier Transportation, Ahmedabad, [email protected] 1. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] 1. Mr. Manikandan AVM, SRMIST
2. Mr. Hariharasudhan – Johnson Controls, Pune, [email protected] 2. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected] 2. Dr. Diwakar R Marur, SRMIST
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 12
Course Code
18ECC103J Course Name
DIGITAL ELECTRONIC PRINCIPLES Course
Category C Professional Core
L T P C
3 0 2 4
Pre-requisite Courses
18EES101J Co-requisite
Courses Nil
Progressive Courses
18ECC203J, 18ECC206J, 18ECE206J
Course Offering Department Electronics and Communication Engineering Data Book / Codes/Standards Nil
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Understand binary codes, digital arithmetic operations and able to simplify Boolean logic expressions 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
CLR-2 : Describe how basic TTL and CMOS gates operate at the component level
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om)
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Too
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Soc
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& C
ultu
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Env
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Sus
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abili
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Eth
ics
Indi
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al &
Tea
m W
ork
Com
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Pro
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Mgt
. & F
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h
CLR-3 : Able to design simple combinational logics using basic gates and MSI circuits
CLR-4 : Familiarize with basic sequential logic components: flip-flops, registers, counters and their usage, and able to design and analyze sequential logic circuits and Finite State Machines.
CLR-5 : Know how to implement logic circuits using PLDs.
CLR-6 : Use modern engineering tools such as PSPICE / Logisim to carry out design experiments and gain experience with instruments and methods used by technicians and electronic engineers
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Simplify Boolean expressions; carry out arithmetic operations with binary numbers; apply parity method for error detection and correction.
1 90 75 H - - - - - - - - - - - - - -
CLO-2 : Explain the operational characteristics / properties of digital ICs; implement gates as well as other types of IC devices using two major IC technologies, TTL and CMOS.
1 80 70 H - - - - - - - - - - - - - -
CLO-3 : Identify eight basic types of fixed-function combinational logic functions and demonstrate how the devices / circuits can be used in building complete digital systems such as computers.
2,3 90 75 - M H - H - - - - - - - - - -
CLO-4 : Analyze and design Mealy and Moore models of sequential circuits using several types of flip-flops. 2,3 90 75 - M H - H - - - - - - - - - -
CLO-5 : Implement multiple output combinational logic circuits using PLDs; Explain the operation of a CPLD and FPGA. 2 80 75 - M H - L - - - - - - - - - -
CLO-6 : Solve specific design problem, which after completion will be verified using modern engineering tools such as PSPICE / Logisim
2 90 75 - M H - H - - - H - - - M - L
Duration (hour)
Binary Codes, Digital Arithmetic and Simplification of Boolean Functions
Logic Families Combinational Systems Sequential Systems Memory and Programmable Logic
15 15 15 15 15
S-1 SLO-1
Binary Codes, Digital Arithmetic and Simplification of Boolean Functions
Introduction Binary arithmetic units Flip-flop and Latch: SR latch, RAM Memory decoding
SLO-2 Error detecting codes TTL Logic Family Adder JK flip-flop, T flip-flop, D flip-flop ROM
S-2 SLO-1 Error correcting code Totem-pole TTL Design of Half adder Master-slave RS flip-flop
Programmable Logic Devices (PLDs): Basic concepts
SLO-2 Hamming Code open-collector and tristate TTL Design of Full adder Master-slave JK flip-flop PROM
S-3 SLO-1 Arithmetic number representation
Schottkey TTL, standard TTL characteristics
Subtractor Registers & Counters PROM as PLD
SLO-2 Binary arithmetic Metal Oxide Semiconductor logic families Design subtractor using logic gates Shift registers (SISO, SIPO, PISO, PIPO) Programmable Array Logic (PAL)
S 4-5
SLO-1 LAB 1: Study of logic gates
LAB 4: Design and implement encoder and decoder using logic gates
LAB 7: Implement combinational logic functions using standard ICs
LAB 10: Design and implement Synchronous Counters
LAB 13: Construct combinational circuit using Logisim SLO-2
S-6 SLO-1 Hexadecimal arithmetic N-MOS n-bit parallel adder & subtractor Universal shift register Programmable Array Logic (PAL)
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 13
SLO-2 Hexadecimal arithmetic P-MOS look ahead carry generator Counters: Asynchronous/Ripple counters Programmable Logic Array (PLA)
S-7 SLO-1 BCD arithmetic simplification CMOS logic circuits Decoder Synchronous counters, Modulus-n Counter Programmable Logic Array (PLA)
SLO-2 Minimization of Boolean Functions: Algebraic simplification
Characteristics of MOS logic Encoder Ring counter, Johnson counter Design combinational circuits using PLD’s
S-8 SLO-1 Problems on Algebraic simplification
Compare MOS logic circuits(CMOS) with TTL digital circuit
Multiplexer Up-Down counter Design combinational circuits using PLD’s
SLO-2 Karnaugh map simplification Electrical characteristics Demultiplexer Mealy and Moore model Design combinational circuits using PLD’s
S 9-10
SLO-1 LAB 2: Design and implement Adder and Subtractor using logic gates
LAB 5: Design and implement Multiplexer and Demultiplexer using logic gates
LAB 8: Verify characteristic table of flip-flops
LAB 11: Construct and verify shift registers LAB 14: Model Practical Examination SLO-2
S-11 SLO-1 Problems on Karnaugh map simplification Fan-out Code converters Synchronous (Clocked) sequential circuits
Design of combinational circuits using PLD’s
SLO-2 Problems on Karnaugh map simplification Propagation Delay Magnitude comparators Synchronous (Clocked) sequential circuits Design sequential circuits using PLD’s
S-12 SLO-1 Quine McCluskey Power dissipation Magnitude comparators Synchronous (Clocked) sequential circuits Design sequential circuits using PLD’s
SLO-2 Tabulation method Noise margin Parity generators (Odd parity) Analyze and design synchronous sequential circuits
Design sequential circuits using PLD’s
S-13 SLO-1
Problems on Quine McCluskey or Tabulation method.
Supply voltage levels Parity generators (Even parity) State reduction Design sequential circuits using PLD’s
SLO-2 Exercise problems using Tabulation method
Operational voltage levels Implementation of combinational logic by standard IC’s.
State assignment Design sequential circuits using PLD’s
S 14-15
SLO-1 Lab 3: Design and Implement 2-bit Magnitude Comparator using logic gates
LAB-6: Design and implement code converters using logic gates
LAB 9: Construct and verify 4-bit ripple counter, Mod-10/Mod-12 ripple counters
Lab 12: Construct mini project work LAB 15: University Practical Exam SLO-2
Learning Resources
1. Morris Mano M, Michael D. Ciletti, Digital Design with an Introduction to the Verilog HDL, 5th ed., Pearson Education, 2014
2. Charles H Roth (Jr), Larry L. Kinney, Fundamentals of Logic Design, 5th ed., Cengage Learning India Edition, 2010
3. Thomas L. Floyd, Digital Fundamentals, 10th ed., Pearson Education, 2013
4. Ronald J. Tocci, Digital System Principles and Applications, 10th ed., Pearson Education, 2009 5. Donald P Leach, Albert Paul Malvino, Goutam Saha, Digital Principles and Applications, 6th ed., Tata-
Mcgraw Hill, 2008 6. LAB MANUAL, Department of ECE, SRM University
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)#
Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
r. Level 1 Remember
20% 20% 15% 15% 15% 15% 15% 15% 15% 15% Understand
Level 2 Apply
20% 20% 20% 20% 20% 20% 20% 20% 20% 20% Analyze
Level 3 Evaluate
10% 10% 15% 15% 15% 15% 15% 15% 15% 15% Create
Total 100 % 100 % 100 % 100 % -
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Mr. Anuj Kumar, Bombardier Transportation, Ahmedabad, [email protected] 1. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] 1. Mr. Viswanathan B, SRMIST
2. Mr. Hariharasudhan - Johnson Controls, Pune, [email protected] 2. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected]
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 14
Course Code
18ECC104T Course Name
SIGNALS AND SYSTEMS Course
Category C Professional Core
L T P C
3 1 0 4
Pre-requisite Courses
Nil Co-requisite
Courses 18MAB201T
Progressive Courses
18ECC204J, 18ECS201T, 18ECE240T, 18ECE241J
Course Offering Department Electronics and Communication Engineering Data Book / Codes/Standards Nil
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Know about requirements of signal and system analysis in communication. 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
CLR-2 : Understand the analysis of Periodic and Aperiodic Continuous time Signals using Fourier series and transforms
Leve
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d A
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)
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& D
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Ana
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s, D
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Mod
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Too
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Soc
iety
& C
ultu
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Env
ironm
ent &
Sus
tain
abili
ty
Eth
ics
Indi
vidu
al &
Tea
m W
ork
Com
mun
icat
ion
Pro
ject
Mgt
. & F
inan
ce
Life
Lon
g Le
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ng
PS
O–1
: Pro
fess
iona
l Ach
ieve
men
t
PS
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2: P
roje
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anag
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t T
echn
ique
s
PS
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3: A
naly
ze &
Res
earc
h CLR-3 : Educate about Continuous time system through Laplace transform and Convolution integral
CLR-4 : Understand the characterization of the Discrete time signals and system through DTFT, Convolution sum
CLR-5 : Understand the concept of Z-Transform for the analysis of DT system
CLR-6 : Develop expertise in time-domain and frequency domain approaches to the analysis of continuous and discrete systems and also the ability to apply modern computation software tool for the analysis of electrical engineering problems
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Understand the various classifications of Signals and Systems 1 65 60 H - - - - - - - - - - - - - -
CLO-2 : Analyze Periodic and Aperiodic Continuous time Signals using Fourier series and Fourier Transform 2 65 60 - H - - - - - - - - - - - - - CLO-3 : Analyze and characterize the Continuous time system through Laplace transform and Convolution integral. 2 65 60 - H - - - - - - - - - - - - -
CLO-4 : Analyze and characterize the Discrete time signals and system through DTFT, Convolution sum 2 65 60 - H M - - - - - - - - - - - -
CLO-5 : Analyze and characterize the Discrete time system using Z transform 2 65 60 - H M - - - - - - - - - - - L
CLO-6 : Apply the mathematical techniques used for continuous-time signal and discrete-time signal and system analysis 2 65 60 - H - M M - - - - - - - L - -
Duration (hour)
Classification of Signals and Systems Analysis of Continuous Time Signals Analysis of LTI CT System Analysis of DT Signals and Systems Analysis of LTI DT System
using Z-Transform
12 12 12 12 12
S-1 SLO-1 Introduction to signals and systems Introduction to Fourier series System modeling Representation of sequences Z transform – introduction
SLO-2 Requirements of signal and system analysis in communication
Representation of Continuous time Periodic signals
Description of differential equations Discrete frequency spectrum and range Region of convergence of finite duration sequences
S-2 SLO-1 Continuous time signals (CT signals)
Fourier series: Trigonometric representation
Solution of Differential equation Discrete Time Fourier Transform (DTFT) – Existence
Properties of ROC
SLO-2 Discrete time signals (DT signals) Fourier series: Trigonometric representation
Differential equation: Zero initial conditions DTFT of standard signals Properties of ROC
S-3 SLO-1
Representation of signals: Step, Ramp, Pulse, Impulse
Fourier series: Cosine representation Differential equation: Zero state response Properties of DTFT Properties of Z transform
SLO-2 Representation of signals: Sinusoidal, Exponential
Fourier series: Cosine representation Differential equation: Zero Input response Properties of DTFT Properties of Z transform
S-4 SLO-1 Basic operation on the signals Symmetry conditions Total Response Inverse DTFT Unilateral z transforms
SLO-2 Problems on signal operations Properties of Continuous time Fourier series
Step response Practice on IDTFT Properties of z transform
S-5 SLO-1
Classification of CT and DT signals: Periodic & Aperiodic signals.
Practice problems on Fourier series Impulse response Impulse response of a system with DTFT Bilateral Z transforms
SLO-2 Classification of CT and DT signals: Deterministic & Random signals.
Practice problems on Fourier series Frequency response Frequency response of a system with DTFT
Properties of z transform
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 15
S-6 SLO-1 Energy signal Gibb’s Phenomenon Convolution integral Practice problems Relation between DTFT and Z transform
SLO-2 Power signal Parseval’s relation for power signals Properties of convolution Practice problems Practice problems
S-7 SLO-1 Even & Odd signals Power density spectrum, Practice Problems
Solution of linear constant coefficient difference equations
condition for causality in Z domain
SLO-2 Even & Odd signals Frequency spectrum. Practice Problems Initial conditions condition for stability in Z domain
S-8 SLO-1 CT systems and DT systems Fourier transform: Introduction
Signal and system analysis with Laplace transform
Solution of difference equations Inverse Z transform
SLO-2 Classification of systems: Static & Dynamic Representation of Continuous time signals Convergence of Laplace Transform Zero input response Power series expansion
S-9 SLO-1 Superposition theorem
Properties of Continuous time Fourier transform
Properties of Laplace transform Solution of difference equations with Zero state response
Inverse Z transform with Partial fraction
SLO-2 Linear & Nonlinear system Properties of Continuous time Fourier transform
Properties of Laplace transform Total response Inverse Z transform with Partial fraction
S-10 SLO-1 Time-variant & Time-invariant system Parseval’s relation for energy signals Inverse Laplace transform Evaluation of Impulse response Residue method
SLO-2 Time-invariant system Energy density spectrum Problems Evaluation of Step response Convolution method
S-11 SLO-1 Causal system
Analysis of LTI system using Fourier Transform
Analysis and characterization of LTI system using Laplace transform
Convolution Properties Analysis and characterization of DT system using Z-transform
SLO-2 Noncausal system Analysis of LTI system using Fourier Transform
Analysis and characterization of LTI system using Laplace transform
Convolution Sum Analysis and characterization of DT system using Z-transform
S-12 SLO-1 Stable & Unstable,LTI System Practice problems on Fourier Transform Practice problems on Laplace transform Circular convolution
Practice problems on LTI-DT systems in Z transform
SLO-2 Unstable, LTI System Practice problems on Fourier Transform Practice problems on Laplace transform Frequency response Practice problems on LTI-DT systems in Z transform
Learning Resources
1. Alan V Oppenheim, Ronald W. Schafer Signals & Systems, 2nd ed., Pearson Education, 2015 2. P.Ramakrishna Rao, Shankar Prakriya, Signals & Systems, 2nd ed., McGraw Hill Education, 2015 3. Simon Haykin, Barry Van Veen, Signals and Systems, 2nd ed., John Wiley & Sons Inc., 2007 4. Lathi B.P, Linear Systems & Signals, 2nd ed., Oxford Press, 2009
5. John G. Proakis, Manolakis, Digital Signal Processing, Principles, Algorithms and Applications, 4th ed., Pearson Education, 2007.
6. Software: Matlab Student Version Release 2011a, Mathworks, Inc. The Matlab Student Version and toolboxes may be purchased through the Mathworks website at http://www.mathworks.com/
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)# Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
40 % - 30 % - 30 % - 30 % - 30% - Understand
Level 2 Apply
40 % - 40 % - 40 % - 40 % - 40% - Analyze
Level 3 Evaluate
20 % - 30 % - 30 % - 30 % - 30% - Create
Total 100 % 100 % 100 % 100 % 100 %
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers
Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Mr. Anuj Kumar, Bombardier Transportation, Ahmedabad, [email protected] 1. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] 1. Dr. A. Ruhan Bevi, SRMIST
2. Mr. Hariharasudhan - Johnson Controls, Pune, [email protected] 2. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected] 2. Dr. D. Malathi, SRMIST
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 16
Course Code
18ECC105T Course Name
ELECTROMAGNETICS AND TRANSMISSION LINES Course
Category C Professional Core
L T P C
3 0 0 3
Pre-requisite Courses
18PYB101J Co-requisite
Courses Nil
Progressive Courses
18ECC301T
Course Offering Department Electronics and Communication Engineering Data Book / Codes/Standards Clark’s Table, IS : 456-2000
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Gain knowledge on the basic concepts and insights of Electric field 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
CLR-2 : Gain knowledge on the basic concepts and insights of Magnetic field and Emphasize the significance of Maxwell’s equations.
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Too
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Soc
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& C
ultu
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Env
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ent &
Sus
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abili
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Eth
ics
Indi
vidu
al &
Tea
m W
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Com
mun
icat
ion
Pro
ject
Mgt
. & F
inan
ce
Life
Lon
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PS
O–1
: Pro
fess
iona
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men
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PS
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s
PS
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naly
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Res
earc
h CLR-3 : Interpret the wave propagation in guided waveguide.
CLR-4 : Acquire the fundamental knowledge on Transmission Line Theory. CLR-5 : Acquire the knowledge on transmission line parameter calculation and impedance matching concepts.
CLR-6 : Acquire knowledge on theoretical concepts and analysis techniques to find solutions for problems related to electromagnetic wave propagation and Transmission line Theory.
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Apply the concepts and knowledge to solve problems related to electric field. 2 60 60 M H - - - - - - - - - - - - L CLO-2 : Analyze the concepts of Magnetic field and Maxwell’s equations in the real world application. 2 60 60 H M - - - - - - - - - - - - L CLO-3 : Translate the phenomenon of guided wave propagation and its mode of propagation. 1 60 60 H M - - - - - - - - - - - - L CLO-4 : Describe the importance of transmission line theory applicable to low frequency transmission lines. 1 60 60 M H - - - - - - - - - - - - L CLO-5 : Solve transmission line parameter and impedance matching through analytical and graphical methods. 2 60 60 M H - - - - - - - - - - - - M
CLO-6 : Demonstrate how electromagnetic waves are generated using Maxwell’s equations and how Transmission lines are used to transfer electromagnetic energy from one point to another with minimum losses over a wideband of frequencies.
2 60 60 M H - - - - - - - - - L - - H
Duration (hour)
Electrostatics Magnetostatics and Maxwells Equations Electromagnetic Waves and
Waveguides Transmission Line Theory
Transmission Line Calculator and Impedance Matching
9 9 9 9 9
S-1 SLO-1 Introduction Energy density in electrostatic field Introduction Transmission line parameters Introduction
SLO-2 Rectangular co-ordinate Problem discussion. Waves in general Transmission line parameters Smith chart Introduction
S-2 SLO-1 Cylindrical & Spherical Co-ordinate
Biot savart law-Magnetic field intensity due to Infinite line charge
Plane wave in lossless dielectric Transmission line equivalent circuit Reflection coefficient, Standing wave ratio Input impedance calculation in smith chart
SLO-2 Review of vector calculus H- due finite and semi finite line charge Plane wave in free space Explanation Practice problems.
S-3 SLO-1 Coulomb’s Law and field intensity
Ampere’s circuital law& application: Infinite line current
Plane wave in good conductor Transmission line equation derivation Single stub matching Introduction
SLO-2 Problem based on coulomb’s law Infinite Sheet current Problems based on plane waves in lossless, free space and good conductor
Problem discussion. Procedure for single stub matching
S-4 SLO-1
Electric field due to continuous charge distribution-.Concept
Infinitely long coaxial Transmission line Rectangular waveguide Transmission line characteristics: lossless line
Problems solving in smith chart
SLO-2 Derivation of E due Infinite Line charge Problem based on ACL. Rectangular waveguide-Problems Distortionless line. Problems solving in smith chart
S-5 SLO-1 Electric field due to sheet charge Magnetic flux density Transverse Electric (TE) mode Input impedance derivation Impedance matching using Quarter wave transformer
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 17
SLO-2 Problem based on sheet charge Problem based on magnetic field and flux. Transverse Electric (TE) mode-problems Problems for input impedance calculation. Problems.
S-6 SLO-1 Electric field due to volume charge Maxwell’s equation for static field Transverse Electric (TE) mode Standing wave ratio Single stub tuner
SLO-2 Electric flux density Faraday’s law Transverse Electric (TE) mode-Problems Calculation of standing wave ratio. Problem discussion
S-7 SLO-1 Gauss law application-point charge Transformer EMF Wave propagation in guide Reflection coefficient Slotted Line (Impedance Measurement)
SLO-2 Electric flux due infinite line charge Motional EMF Problem discussion Problem discussion. Problem discussion
S-8 SLO-1 Electric flux due sheet charge Displacement current. Power Transmission Shorted line, open circuited line Transmission Lines as circuit Elements
SLO-2 Electric flux due coaxial cable Maxwell’s equation in time varying field Calculation of Pavg and Ptotal Matched line Problem discussion
S-9 SLO-1 Relation between E&V Time varying potential concepts Power attenuation Power calculations Additional smith chart problem solving.
SLO-2 Electric dipole and flux lines Time varying potential derivation. Calculation of αTE and αTE Problem discussion. Additional smith chart problem solving.
Learning Resources
1. Matthew N. O. Sadiku., S. V. Kulkarni, Elements of Electromagnetics, 6th ed., Oxford University Press, 2015 2. G. S. N. Raju, Electromagnetic Field Theory and Transmission Lines, Pearson Education, 2006 3. Nannapaneni Narayana Rao, Principles of Engineering Electromagnetics,6th ed., Pearson Education, 2016
4. William H. Hayt,Jr., John A.Buck., Engineering Electromagnetics, 8th ed., Tata McGraw-Hill 2012 5. John D.Ryder, Networks, Lines and Fields, PHI, 2009
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)# Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
40 % - 30 % - 30 % - 30 % - 30% - Understand
Level 2 Apply
40 % - 40 % - 40 % - 40 % - 40% - Analyze
Level 3 Evaluate
20 % - 30 % - 30 % - 30 % - 30% - Create
Total 100 % 100 % 100 % 100 % 100 %
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Mr. Anuj Kumar, Bombardier Transportation, Ahmedabad, [email protected] 1. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] 1. Dr. P. Eswaran, SRMIST
2. Mr. Hariharasudhan - Johnson Controls, Pune, [email protected] 2. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected]
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 18
Course Code
18ECC201J Course Name
ANALOG ELECTRONIC CIRCUITS Course
Category C Professional Core
L T P C
3 0 2 4
Pre-requisite Courses
18ECC102J Co-requisite
Courses 18ECC202J
Progressive Courses
Nil
Course Offering Department Electronics and Communication Engineering Data Book / Codes/Standards Nil
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Understand the operation and design of BJT amplifier circuits for a given specification 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
CLR-2 : Understand the operation and design of MOSFET amplifier circuits for a given specification
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& C
ultu
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Sus
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Eth
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Indi
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Pro
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: Pro
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3: A
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Res
earc
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CLR-3 : Understand the effects of negative feedback on amplifier circuits, and analyze the different RC and LC oscillator circuits to determine the frequency of oscillation
CLR-4 : Understand the operation and design of various types of power amplifier circuits.
CLR-5 : Understand how matched transistor characteristics are used in the IC design and to be able to design BJT and MOSFET current sources.
CLR-6 : Gain hands-on experience to put theoretical concepts learned in the course to practice.
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Analyze and design bipolar amplifier circuits to meet certain specifications, and to Analyze the frequency response of amplifier circuits, taking into account various circuit capacitors, to determine the bandwidth of the circuit.
2,3 70 70 L M H - - - - - - - - - - - -
CLO-2 : Analyze and design MOSFET amplifier circuits to meet certain specifications, and to Analyze the frequency response of amplifier circuits, taking into account various circuit capacitors, to determine the bandwidth of the circuit.
2,3 70 70 L M H - - - - - - - - - - - -
CLO-3 : Understand the characteristics and principles of feedback amplifier circuits and oscillator circuits to analyze and design circuits to meet certain specifications.
2,3 70 70 L M H - - - - - - - - - - - -
CLO-4 : Analyze three principle classes of power amplifiers, and determine the maximum possible conversion efficiency of each type of power amplifier
2,3 70 70 L M H - - - - - - - - - - - -
CLO-5 : Design the basic circuit building blocks that are used in the design of IC amplifiers, namely current mirrors and sources 2,3 70 70 L M H - - - - - - - - - - - -
CLO-6 : Analyze and design analog electronic circuits using discrete components, and take measurement of various analog circuits to compare experimental results in the laboratory with theoretical analysis.
3 90 80 - - H - M - - - M - - M H L -
Duration (hour) BJT Amplifiers FET Amplifiers Feedback amplifies & Oscillators Oscillators & Power Amplifiers IC Biasing & Amplifiers with Active Load
15 15 15 15 15
S-1 SLO-1 Overview of DC analysis of BJT circuits Overview of FET DC circuit analysis
Basic feedback concepts, general feedback structure
Crystal Oscillators BJT current sources: Cascode current source, Widlar current source
SLO-2 Overview of BJT models Problem solving Properties of negative feedback Problem solving Multi-transistor current source Problem solving
S-2 SLO-1 AC load line analysis
Graphical analysis, load lines, and small-signal models
Feedback Topologies: Voltage-Series & Current-Series feedback connections
Negative-resistance oscillator FET current sources: 2-transistor MOSFET current source
SLO-2 Problem solving Problem solving Problem solving Problem solving Problem solving
S-3 SLO-1
AC analysis of Common-Emitter BJT amplifier config. using hybrid-π model
AC analysis of Common-Source MOSFET amplifier configuration
Feedback Topologies: Voltage-Shunt & Current-Shunt feedback connections
Power Amplifiers: Definitions and amplifier types
FET current sources: Cascode current mirror and Wilson current mirror
SLO-2 Problem solving Problem solving Problem solving Q point placement Problem solving
S 4-5
SLO-1 Lab 1: Learning to design amplifier and oscillator circuits
Lab 4: Design & analyze differential amplifier with resistive load
Lab 7: Design and analyze RC oscillators Lab 10: BJT & FET Current Sources Lab 13: Design and analyze differential amplifier with active load SLO-2
S-6 SLO-1 AC analysis of Common-Base BJT amplifier configuration using hybrid-π model
AC analysis of Common-Gate MOSFET amplifier configuration
Practical Feedback Amplifier Circuits Maximum dissipation hyperbola Analysis of CE BJT amplifier circuit with active load
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 19
SLO-2 Problem solving Problem solving Problem solving Heat sink Problem solving
S-7 SLO-1
AC analysis of Common-Collector BJT amplifier config. using hybrid-π model
AC analysis of Common-Drain MOSFET amplifier configuration
Oscillators: Principles of Oscillation Class A amplifier Analysis of CS FET amplifier circuit with active load
SLO-2 Problem solving Problem solving Types of Oscillators Problem solving Problem solving
S-8 SLO-1
Multi-stage amplifier configurations: CE - CE, CE - CC amplifiers
BiFET amplifier configuration Audio Frequency Oscillators: RC Phase-Shift Oscillator
Class B and Class AB push-pull amplifiers DC and small-signal analysis of basic BJT differential pairs
SLO-2 Problem solving Problem solving Problem solving Problem solving Problem solving
S 9-10
SLO-1 Lab 2: Design and analyze BJT amplifier configurations
Lab 5: Design and analyze negative feedback amplifier configurations
Lab 8: Design and analyze LC oscillators Lab 11: Design and analyze BJT CE amplifier with active load
Lab 14: Model Practical Examination SLO-2
S-11 SLO-1
Multi-stage amplifier configurations: CE - CB, and CC - CC amplifiers
Low Frequency response analysis of a basic FET CS amplifier
Audio Frequency Oscillators: Wein Bridge Oscillator
Class C amplifiers DC and small-signal analysis of basic FET differential pairs
SLO-2 Problem solving Problem Solving Problem Solving Problem solving Problem solving
S-12 SLO-1
Low Frequency response analysis of a basic BJT CE amplifier
High Frequency response analysis of a basic FET CS amplifier
Radio Frequency Oscillators: Hartley Oscillator
Class D and Class E amplifiers Analysis of BJT differential amplifier with active load
SLO-2 Problem Solving Problem Solving Problem solving Amplifier distortions Problem solving
S-13 SLO-1
High Frequency response analysis of a basic BJT CE amplifier
Design problems in MOSFET amplifier configurations
Radio Frequency Oscillators: Colpitts & Clapp Oscillators
IC Biasing & Amplifiers with Active Load: BJT current sources: 2- & 3-transistor current sources
Analysis of FET differential amplifier with active load
SLO-2 Problem Solving Operational voltage levels Problem solving Problem solving Problem solving
S 14-15
SLO-1 Lab 3: Design and analyze multistage amplifier configurations
Lab 6: Design and analyze MOSFET amplifier configurations
Lab 9: Classes of power amplifier (efficiency calculation)
Lab 12: Design and analyze FET CS amplifier with active load
Lab 15: End Semester Practical Examination SLO-2
Learning Resources
1. David A. Bell, Electronic Devices and Circuits, 5th ed., Oxford University Press, 2015 2. Donald Neamen, Electronic Circuits: Analysis and Design, 3rd ed., McGraw-Hill Education, 2011 3. Muhammad Rashid, Microelectronic Circuits: Analysis & Design, 2nd ed., Cengage Learning, 2010 4. Adel S. Sedra, Kenneth C. Smith, Microelectronic Circuits: Theory and Applications, OUP, 2014
5. Robert L. Boylestad, Louis Nashelsky, Electronic Devices and Circuit Theory, 11th ed., Pearson Education, 2013
6. Albert P. Malvino, David J. Bates, Electronic Principles, 8th ed., Tata McGraw Hill, 2015
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)#
Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
r. Level 1 Remember
20% 20% 15% 15% 15% 15% 15% 15% 15% 15% Understand
Level 2 Apply
20% 20% 20% 20% 20% 20% 20% 20% 20% 20% Analyze
Level 3 Evaluate
10% 10% 15% 15% 15% 15% 15% 15% 15% 15% Create
Total 100 % 100 % 100 % 100 % -
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Mr. Anuj Kumar, Bombardier Transportation, Ahmedabad, [email protected] 1. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] 1. Mr. Manikandan AVM, SRMIST
2. Mr. Hariharasudhan - Johnson Controls, Pune, [email protected] 2. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected] 2. Dr. M. Sangeetha, SRMIST
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 20
Course Code
18ECC202J Course Name
LINEAR INTEGRATED CIRCUITS Course
Category C Professional Core
L T P C
3 0 2 4
Pre-requisite Courses
18ECC102J Co-requisite
Courses 18ECC201J
Progressive Courses
Nil
Course Offering Department Electronics and Communication Engineering Data Book / Codes/Standards Nil
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Study the basic principles, configurations and practical limitations of op-amp 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
CLR-2 : Understand the various linear and non-linear applications of op-amp
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Sus
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Eth
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Indi
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Com
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Pro
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Life
Lon
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PS
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naly
ze &
Res
earc
h CLR-3 : Understand the operation and analysis of op-amp oscillators, single chip oscillators and frequency generators
CLR-4 : Identify the active filter types, filter response characteristics, filter parameters and IC voltage regulators.
CLR-5 : Gain knowledge on data converter terminology, its performance parameters, and various circuit arrangements for A/D and D/A conversions.
CLR-6 : Gain hands-on experience to put theoretical concepts learned in the course to practice.
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Infer the DC and AC characteristics of operational amplifiers and its effect on output and their compensation techniques 3 80 70 H M - - - - - - - - - - - - -
CLO-2 : Elucidate and design the linear and non-linear applications of an opamp and special application ICs 3 85 75 - M H - - - - - - - - - - - -
CLO-3 : Explain and compare the working of multivibrators using special application IC 555 and general purpose opamp 3 75 70 - M H - - - - - - - - - - - - CLO-4 : Classify and comprehend the working principle of data converters and active filters 3 85 80 - M H - - - - - - - - - - - -
CLO-5 : Illustrate the function of application specific ICs such as Voltage regulators, PLL and its application in communication 3 85 75 - M H - - - - - - - - - M - H
CLO-6 : Analyze and design electronic circuits and systems using linear ICs, and take measurement of various analog circuits to compare experimental results in the laboratory with theoretical analysis
3 85 75 - M H - M - - - M - - - H L -
Duration (hour) 15 15 15 15 15
S-1 SLO-1 Op-amp symbol, terminals, packages
Basic op-amp circuits: Inverting & Non-inverting voltage amplifiers
Waveform Generators: Sine-wave Generators - Design
Filters: Comparison between Passive and Active Networks
Digital to Analog Conversion: DAC Specifications
SLO-2 Op-amp-Specifications Voltage follower Implementation & Solving problems Active Network Design Solving problems
S-2 SLO-1 Block diagram Representation of op-amp Summing, scaling & averaging amplifiers, Square Wave generators- Design Filter Approximations Weighted Resistor DAC
SLO-2 Ideal op-amp & practical op-amp - Open loop & closed loop configurations
AC amplifiers Implementation & Solving problems Design of LPF & Solving problems Solving problems
S-3 SLO-1 DC performance characteristics of op-amp
Linear Applications: Instrumentation Amplifiers
Triangle wave generators Design of HPF & Solving problems R-2R Ladder DAC
SLO-2 Solving Problems Instrumentation Amplifiers, Solving Problems
Saw-tooth Wave generators. Design of BPF& Solving problems Solving problems
S 4-5
SLO-1 Lab-1:Basic op-amp circuits Lab 4: Comparators
Lab 7: Waveform generators: using op-amp & 555 Timer
Lab 10: Design of LPF, HPF, BPF and Band Reject Filters
Lab 13: Flash Type ADC SLO-2
S-6 SLO-1 AC performance characteristics of op-amp V-to-I Converters IC 555 Timer: Circuit schematic Design of Band Reject Filters Inverted R-2R Ladder DAC
SLO-2 Solving Problems I-to-V converters Operation and its applications Solving problems Monolithic DAC
S-7 SLO-1 Frequency response Differentiators IC 555 Timer: Monostable operation State Variable Filters – All Pass Filters,
Analog to Digital conversion: ADC specifications
SLO-2 Frequency response Integrators Applications & Solving problems Solving problems Solving problems
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 21
S-8 SLO-1 Frequency compensation
Non-linear Applications: Precision Rectifiers
IC 555 Timer: Astable operation Switched Capacitor Filters. Ramp Type ADC
SLO-2 Frequency compensation Wave Shaping Circuits (Clipper and Clampers)
Applications & Solving problems Solving problems Solving problems
S 9-10
SLO-1 Lab 2: Integrators and Differentiators Lab 5: Wave shaping circuits
Lab 8: Waveform generators: using op-amp & 555 Timer
Lab 11: IC Voltage regulators Lab 14: Simulation experiments using EDA tools SLO-2
S-11 SLO-1 Basic op-amp internal schematic Log and Antilog Amplifiers, PLL: Operation of the Basic PLL
Voltage Regulators: Basics of Voltage Regulator
Successive Approximation ADC
SLO-2 operations of blocks Analog voltage multiplier circuit and its applications,
Closed loop analysis of PLL Specifications and characteristic parameters
Solving problems
S-12 SLO-1 Basic op-amp internal schematic
Operational Trans-Conductance Amplifier (OTA)
Voltage Controlled Oscillator Linear Voltage Regulators using Op-amp, Dual Slope ADC
SLO-2 operations of blocks Comparators : operation Solving problems IC Regulators (78xx, 79xx, LM 317, LM 337, 723),
Flash Type ADC,
S-13 SLO-1 Review of data sheet of an op-amp. Comparators applications PLL applications Switching Regulators -operation Solving problems on Flash Type ADC,
SLO-2 Solving Problems Sample and Hold circuit. Solving problems Types Monolithic ADC
S 14-15
SLO-1 Lab 3: Rectifiers
Lab 6: Waveform generators: using op-amp & 555 Timer
Lab 9: Design of LPF, HPF, BPF and Band Reject Filters
Lab 12: R-2R ladder DAC Lab 15: Simulation experiments using EDA tools SLO-2
Learning Resources
1. Ramakant A. Gayakwad, Op-Amps and Linear Integrated Circuits, 4th ed., Prentice Hall, 2000 2. David A. Bell, Operational Amplifiers and Linear ICs, 3rd ed., OUP, 2013 3. Roy Choudhury, Shail Jain, Linear Integrated Circuits, 4th ed., New Age International Publishers, 2014 4. Robert F. Coughlin, Frederick F. Driscoll, Operational-Amplifiers and Linear Integrated Circuits, 6th ed.,
Prentice Hall, 2001 5. Sergio Franco, Design with operational amplifier and analog integrated circuits, McGraw Hill, 1997
6. LABORATORY MANUAL, Department of ECE, SRM University 7. David A Bell, Laboratory Manual for Operational Amplifiers & Linear ICs, 2nd ed., D.A. Bell, 2001 8. David La Lond, Experiments in Principles of Electronic Devices and Circuits, Delmar Publishers, 1993 9. Muhammed H Rashid, Introduction to PSpice using OrCAD for circuits and electronics, 3rd ed., Pearson,
2004 10. L. K. Maheshwari, M. M. S. Anand, Laboratory Experiments and PSPICE Simulations in Analog
Electronics, PHI, 2006
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)# Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
20% 20% 15% 15% 15% 15% 15% 15% 15% 15% Understand
Level 2 Apply
20% 20% 20% 20% 20% 20% 20% 20% 20% 20% Analyze
Level 3 Evaluate
10% 10% 15% 15% 15% 15% 15% 15% 15% 15% Create
Total 100 % 100 % 100 % 100 % -
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Mr. Anuj Kumar, Bombardier Transportation, Ahmedabad, [email protected] 1. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] 1. Mr. Manikandan AVM, SRMIST
2. Mr. Hariharasudhan - Johnson Controls, Pune, [email protected] 2. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected] 2. Dr. M. Sangeetha, SRMIST
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 22
Course Code
18ECC203J Course Name
Microprocessor, Microcontroller and Interfacing Techniques Course
Category C Professional Core
L T P C
3 0 2 4
Pre-requisite Courses
18ECC103J Co-requisite
Courses Nil
Progressive Courses
18ECE204J, 18ECE205J
Course Offering Department Electronics and Communication Engineering Data Book / Codes/Standards Nil
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Understand basic architecture of Intel 8086 microprocessor and Intel 8051 Microcontroller 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
CLR-2 : Familiarize the students with the programming and interfacing of microprocessors and microcontrollers with memory and peripheral chips
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Tea
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Res
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CLR-3 : Interface a microprocessor / microcontroller to external I/O devices and perform I/O device programming in assembly
CLR-4 : Use the computer to write and assemble ALPs and also run them by downloading them to the target microprocessor
CLR-5 : Understand the hardware / software interrupts and their applications, and as well the serial port programming CLR-6 : Provide strong foundation for designing real world applications using microprocessors and microcontrollers.
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Apply a basic concept of digital fundamentals to Microprocessor based personal computer system 1 60 70 - H - - L - - - - - - - - -
CLO-2 : Solve basic binary math operations using the microprocessor. / microcontroller 2 60 70 M - - - - - - - - - M - - -
CLO-3 : Demonstrate programming proficiency using the various addressing modes of the target microprocessor / microcontroller 3 60 70 - M H - H - - - - - - - - L
CLO-4 : Distinguish and analyze the properties of Microprocessors & Microcontrollers. 1 60 70 - M - - - - - - - - H - - - CLO-5 : Illustrate their practical knowledge through laboratory experiments. 3 60 70 - M M - H - - - - H - - - H
CLO-6 : Design, interface and program memory chips and various peripheral chips with microprocessor / microcontroller 3 60 70 - - M - H - - - - - H L - M
Learning Unit / Module 1:
Intel 8086 – Architecture, Signals and Features
Learning Unit / Module 2: Programming with Intel 8086
Learning Unit / Module 3: 8086 Interfacing with Memory and
Programmable Devices
Learning Unit / Module 4: Intel 8051 – Architecture and
Programming
Learning Unit / Module 5: Interfacing of 8051
Duration (hour) 15 15 15 15 15
S-1 SLO-1
Introduction: History of computers, Block diagram of a microcomputer
Addressing modes of 8086 Semiconductor memory interfacing Introduction: Differences between microprocessor and microcontroller
8051 parallel ports, and
SLO-2 Intel 80x86 evolutions Dynamic RAM interfacing Intel’s family of 8-bit microcontrollers, and feature of 8051 microcontroller
its programming
S-2 SLO-1 Features of 8086 microprocessor
Instruction Set of 8086: Data Transfer Instructions
Programmable Peripheral Interface 8255 Architecture of 8051 8051 timers, and
SLO-2 Register organization of 8086 Example programs Interfacing 8255 with 8086 and programming
Architecture of 8051 its programming
S-3 SLO-1 Architecture of 8086
Data Conversion Instructions, Arithmetic Instructions
Interfacing ADC with 8086 and programming
Signal descriptions of 8051 8051 interrupts, and
SLO-2 Architecture of 8086 Example programs Interfacing DAC with 8086 and programming
Signal descriptions of 8051 its programming
S-4,5
SLO-1 Lab-1: (a) Learning to Program with 8086 processor kit; Learning the hardware features of the 8086 processor kit
Lab-4: General Purpose Programming in 8086
Lab-7: Interfacing DAC / ADC with 8086 / 8051
Lab-10: Programming timer / counter in 8086 / 8051
Lab-13: Simulation of 8051 using Keil Software SLO-2
S-6 SLO-1 Instruction queue and pipelining
Logical instructions and Processor control instructions
Stepper Motor interfacing – concept Register set of 8051 8051 serial port, and
SLO-2 Segmentation of memory used with 8086 Example programs Example programs Operational features of 8051 its programming
S-7 SLO-1 Methods of generating physical address in 8086
String instructions Programmable Interval Timer 8254 Memory and I/O addressing by 8051 Interfacing program memory with 8086
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 23
SLO-2 Pin signals of 8086: Common signals Example programs Interfacing 8254 with 8086 and programming
Interrupts and Stack of 8051 Interfacing data memory with 8086
S-8 SLO-1 Minimum mode signals Branch Instructions Programmable Interrupt Controller 8259 Addressing modes of 8051
Interfacing input devices: push-button / matrix keypad
SLO-2 Maximum mode signals Example programs Interfacing 8259 with 8086 and programming
Example programs Example programs
S-9,10 SLO-1 Lab-2: General Purpose Programing in
8086 Lab-5: Simulation of 8086 using MASM Software / 8086 Emulator
Lab-8: Interfacing DC motor / stepper motor / servo motor with 8086 / 8051
Lab-11: Programming interrupts in 8086 / 8051
Lab-14: Model Practical Exam SLO-2
S-11 SLO-1 Minimum mode 8086 system, and
Assembly Language Programming of 8086
Programmable Keyboard / Display Controller 8279
8051 Instruction Set: Arithmetic and Logical Instructions
Interfacing display devices: LED / 7-segment / LCD displays
SLO-2 Timings Assembly Language Programming of 8086
Interfacing 8279 with 8086 and programming
Example Programs Example programs
S-12 SLO-1 Maximum mode 8086 system, and Stack structure, and
Programmable Communication Interface 8251 USART
Data Transfer Instructions Interfacing DAC
SLO-2 Timings related programming Interfacing 8251 with 8086 and programming
Example Programs Interfacing ADC
S-13 SLO-1
Intel 8088 Microprocessor: Pins signals and Architecture
Interrupt structure, and DMA Controller 8257 Boolean Variable Instructions and Branch Instructions
Interfacing DC motor / stepper motor / servo motor
SLO-2 Differences between 8086 & 8088 microprocessors
related programming Interfacing 8257 with 8086 and programming
Example Programs Example programs
S-14,15 SLO-1 Lab-3: General Purpose Programing in
8086 Lab-6: Interfacing 8255 with 8086 / 8051
Lab-9: General Purpose Programming in 8051
Lab-10: Programming serial communication in 8086 / 8051
Lab-15: End-Semester Exam SLO-2
Learning Resources
1. K. M. Bhurchandi and A. K. Ray, "Advanced Microprocessors and Peripherals-with ARM and an Introduction to Microcontrollers and Interfacing ", Tata McGraw Hill, 3rd edition 2015
2. MuhammadAli Mazidi and Janice GillispieMazidi, "The 8051 - Microcontroller and Embedded systems", 7th Edition, Pearson Education, 2011.
3. Doughlas.V.Hall, “Microprocessor and Interfacing : Programming and Hardware”, 3rd edition, McGraw Hill, 2015
4. Kenneth.J.Ayala, “8051 Microcontroller Architecture, Programming and Applications”, 3rd edition, Thomson, 2007
5. Subrataghoshal “ 8051 Microcontroller Internals Instructions ,Programming And Interfacing”,2nd edition Pearson 2010
6. Yu-cheng Liu, Glenn A.Gibson, “Microcomputer systems: The 8086/8088 family-Architecture,programming and design”,2nd edition, Prentice Hall of India,2007
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)#
Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
20% 20% 15% 15% 15% 15% 15% 15% 15% 15% Understand
Level 2 Apply
20% 20% 20% 20% 20% 20% 20% 20% 20% 20% Analyze
Level 3 Evaluate
10% 10% 15% 15% 15% 15% 15% 15% 15% 15% Create
Total 100 % 100 % 100 % 100 % 100 % # CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Mr. Anuj Kumar, Bombardier Transportation, Ahmedabad, [email protected] 1. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] 1. Mr. Manikandan AVM, SRMIST
2. Mr. Hariharasudhan - Johnson Controls, Pune, [email protected] 2. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected]
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 24
Course Code
18ECC204J Course Name
DIGITAL SIGNAL PROCESSING Course
Category C Professional Core
L T P C
3 0 2 4
Pre-requisite Courses
18ECC104T Co-requisite
Courses Nil
Progressive Courses
18ECE243J, 18ECE244J, 18ECE245T
Course Offering Department Electronics and Communication Engineering Data Book / Codes/Standards Nil
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Understand the operations involved in digital conversion of analog signals. 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
CLR-2 : Realize a digital filter in direct, cascade and parallel forms. Perform efficient computation of DFT using radix 2 FFT
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& D
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Too
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Soc
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& C
ultu
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Sus
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Eth
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Indi
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Tea
m W
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Com
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Pro
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Mgt
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Life
Lon
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PS
O–1
: Pro
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men
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O –
2: P
roje
ct M
anag
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echn
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s
PS
O –
3: A
naly
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Res
earc
h
CLR-3 : Design digital FIR filter using windowing technique and frequency sampling methods.
CLR-4 : Design IIR filters using both direct method and method involving conversion of analog filter to digital filter
CLR-5 : Understand sampling rate conversion and apply it for applications like QMF, sub band coding.
CLR-6 : Utilize the techniques for digital conversions, filter designs and multi rate signal processing to solve real time problems
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Determine the knowledge of sampling and quantization and understand the errors that arise due to quantization. 1 80 70 H - - - - - - - - - - - - - -
CLO-2 : Understand the concept of DFT and its efficient computation by using FFT algorithm. 1 75 70 - M - - - - - - - - - - - -
CLO-3 : Design FIR filters using several methods 3 75 70 - M H - - - - - - - - - - - H
CLO-4 : Design IIR filters using several methods 3 75 70 - H - - - - - - - - - - - H
CLO-5 : Discuss the basics of multirate DSP and its applications. 1 70 70 - M - - - - - - - - - - - - - CLO-6 : Apply the concepts of digital filter designs and multi rate signal processing for real time signals 2 70 70 - M - - - - - - - - - - M - -
Learning Unit / Module 1: Signals and Waveforms
Learning Unit / Module 2: Frequency Transformations
Learning Unit / Module 3: FIR Filters
Learning Unit / Module 4: IIR Filters
Learning Unit / Module 5: Multirate signal Processing
Duration (hour) 15 15 15 15 15
S-1
SLO-1 Basic Elements of DSP Realization of digital filters Direct form of realization
Design of Linear Phase FIR filters General consideration
Design of digital IIR filters Comparison of FIR and IIR filters
Introduction to Multirate signal processing
SLO-2 Advantages and applications of DSP Cascade form of realization Causality and its implication Characteristics of practical frequency selective filters
Analog IIR filter design Decimation
S-2
SLO-1 Continuous Time vs Discrete time signals Parallel form of realization Frequency response of symmetric FIR filter
Properties of Butterworth filters Interpolation
SLO-2 Continuous valued vs discrete valued signals
Introduction to DFT N is odd Properties of chebyshev filters Comparison of Butterworth and chebyshev filters
Spectrum of interpolated signal
S-3 SLO-1 Concepts of frequency in analog signals Computation of DFT
Frequency response of symmetric FIR filter
Analog IIR filter design Sampling rate conversion by a rational factor I/D
SLO-2 Continuous and discrete time sinusoidal signals
Properties of DFT Periodicity, linearity and symmetry properties
N is even Design of low pass Butterworth filter Anti-aliasing and anti-imaging filters
S-4 SLO-1
Lab 1 :Generation of basic signals Lab 7: Linear convolution Lab 13: Design of digital FIR Low Pass and High Pass filter using rectangular window
Lab 19: Design of analog Butterworth filter
Lab 25: Interpolation SLO-2
S-5 SLO-1
Lab 2: Unit step, ramp and impulse Lab 8: Circular convolution Lab14: Design of digital FIR Band Pass and Band Stop filter using rectangular window
Lab 20: Design of analog Chebyshev filter
Lab 26: Effect of interpolation in frequency domain SLO-2
S-6 SLO-1 Sampling of analog signals Sampling theorem
Circular convolution Frequency response of antisymmetric FIR filter
Analog IIR filter design
Polyphase structure of decimator Polyphase decimation using z transform
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 25
SLO-2 Aliasing Quantization of continuous amplitude signals
Matrix method and concentric circle method
N is odd and N is even Design of low pass Chebyshev filter Polyphase structure of interpolator Polyphase interpolation using z transform
S-7
SLO-1 Analog to digital conversion Sample and hold,
Efficient Computation of the DFT Design of FIR filters Fourier series method
Design of digital filters Impulse invariance method
Advantages of multirate DSP
SLO-2 Quantization and coding Divide and Conquer Approach to Computation of the DFT Using FFT
Need for filter design using window Comparison of various windowing techniques
Design of digital filters Bilinear transformation
Applications of multirate DSP
S-8 SLO-1 Oversampling A/D converters
N Point DFT Decimation-in-Time FFT Radix-2 FFT Algorithm
Filter Design using windowing technique Design of digital filters Impulse invariance method
Practical Applications of multirate DSP
SLO-2 Digital to analog conversion Sample and hold
N Point DFT Decimation-in-Frequency FFT
Rectangular window Design of digital filters Bilinear transformation
interfacing of digital systems with different sampling rates
S-9 SLO-1
Lab 3: Generation of waveforms Lab9: Autocorrelation and cross correlation
Lab 15: Design of digital FIR Low Pass and High Pass filter using Hanning and Hamming window
Lab 21: Design of digital Butterworth filter using impulse invariance method
Lab 27: Decimation SLO-2
S-10 SLO-1
Lab 4: Continuous and discrete time Lab10: Spectrum analysis using DFT Lab 16: Design of digital FIR Band Pass and Band Stop filter using Hanning and Hamming window
Lab 22: Design of digital Butterworth filter using bilinear transformation
Lab 28: Effect of decimation in frequency domain SLO-2
S-11 SLO-1 Oversampling D/A converters
Radix-2 FFT Algorithm Implementation of FFT Using DIT
Filter Design using windowing technique Hanning window
Design of digital Chebyshev filters Practical Applications of multirate DSP Sub band coding of speech signals
SLO-2 Quantization noise Implementation of FFT Using DIF Filter Design using windowing technique Hamming window
Impulse invariance method Filter banks Analysis filter bank
S-12 SLO-1 Errors due to truncation IDFT Filter Design using windowing technique Design of digital Chebyshev filters Synthesis filter bank
SLO-2 Probability of error Using DIT FFT Blackmann window Bilinear transformation Subband coding filterbank
S-13 SLO-1 Errors due to rounding IDFT Design of FIR filters
Frequency transformation in analog domain
Quadrature Mirror Filter
SLO-2 Probability of error Using DIF FFT Frequency sampling method Frequency transformation in digital domain
Alias free filter bank
S-14 SLO-1
Lab 5: Study of sampling theorem Lab 11: Efficient computation of DFT using FFT
Lab 17: Design of digital FIR Low Pass, High Pass, Band pass and band stop filter using Blackmann window
Lab 23: Design of digital Chebyshev filter using impulse invariance method
Lab 29: Design of anti-aliasing filter SLO-2
S-15 SLO-1
Lab 6: Aliasing effects Lab12: Computation of IDFT Lab 18: Design of digital FIR filter using frequency sampling method
Lab 24: Design of digital Chebyshev filter using bilinear transformation
Lab 30: Design of anti-imaging filter SLO-2
Learning Resources
1. John G. Proakis, Dimitris G. Manolakis, “Digital Signal Processing, Principles, Algorithms and Applications”, Pearson Education, 4th edition, 2014
2. Alan V. Oppenheim, Ronald W. Schafer, “Discrete-Time Signal Processing”, Pearson Education, 1st edition, 2015
3. Sanjit Mitra, “Digital Signal Processing –A Computer Based Approach”, McGraw Hill, India, 4th Edition, 2013. 4. Fredric J. Harris, “Multirate Signal Processing for Communication Systems”,1st edition, Pearson Education,
2007
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 26
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)#
Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
20% 20% 15% 15% 15% 15% 15% 15% 15% 15% Understand
Level 2 Apply
20% 20% 20% 20% 20% 20% 20% 20% 20% 20% Analyze
Level 3 Evaluate
10% 10% 15% 15% 15% 15% 15% 15% 15% 15% Create
Total 100 % 100 % 100 % 100 % 100 %
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Mr. Anuj Kumar, Bombardier Transportation, Ahmedabad, [email protected] 1. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] Dr. M.S. Vasanthi,,SRMIST
2. Mr. Hariharasudhan - Johnson Controls, Pune, [email protected] 2. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected]
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 27
Course Code
18ECC205J Course Name
ANALOG AND DIGITAL COMMUNICATION Course
Category C Professional Core
L T P C
3 0 2 4
Pre-requisite Courses
18MAB203T Co-requisite
Courses Nil
Progressive Courses
18ECC301T, 18ECC302J, 18ECE221T & 18ECE223T
Course Offering Department ECE Data Book / Codes/Standards Nil
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Introduce and Understand the need for modulation, various Amplitude modulators/demodulators, frequency modulators and demodulators
1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
CLR-2 : Comprehend the radio transmitters and receivers using the modulators and demodulators and to analyze the noise performance
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(Blo
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Too
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Soc
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& C
ultu
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Env
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Sus
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abili
ty
Eth
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Indi
vidu
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Tea
m W
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Com
mun
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Pro
ject
Mgt
. & F
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Life
Lon
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2: P
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Res
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h
CLR-3 : Introduce basics of Digital modulation and detection techniques
CLR-4 : Analyze the pass band data transmission techniques in terms of probability of error CLR-5 : Introduce basics of spread spectrum techniques and information theory concepts
CLR-6 : Gain hands-on experience to put theoretical concepts learned in the course to practice.
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Understand the concepts of analog modulation and demodulation techniques 2 80 70 M - - - - - - - - H - - H - -
CLO-2 : Learn the function of radio transmitters and receivers and familiarize with noise performance of various receivers 2 85 75 - M H - - - - - - - - - H - - CLO-3 : Understand various digital modulation schemes and matched filter receiver 2 75 70 M - - - - - - - - - - - - M H
CLO-4 : Understand and analyze various digital pass band data transmission schemes 2 85 80 - - - M - - - - - - - - - M -
CLO-5 : Understanding data transmission using spread spectrum and error coding techniques 2 85 75 - H - - - - - - - - - - M - H
CLO-6 : Analyze the operation of analog and digital communication systems and take measurement of various communication systems to compare experimental results in the laboratory with theoretical analysis
2 85 75 - - H - H - - - H - - M - M H
Analog Modulation Radio Transmitters and Receivers Digital Modulation System and
Baseband Detection Passband Data Transmission
Spread Spectrum Techniques and Information theory Concepts
Duration (hour)
15 15 15 15 15
S-1
SLO-1 Modulation, Need for Modulation, AM transmitter : Low Level, Pulse modulation systems, Overview of PAM,PWM,PPM
Overview of ASK, FSK, PSK Spread spectrum Communications, Frequency Hopping Spread Spectrum (FHSS)
SLO-2 Amplitude Modulation, Types of Amplitude Modulation
AM transmitter : High Level Transmitter Pulse modulation systems, Overview of PAM,PWM,PPM
Overview of ASK, FSK, PSK Spread spectrum Communications, Frequency Hopping Spread Spectrum (FHSS)
S-2 SLO-1 Double sideband Full carrier FM transmitter: Direct Method
Pulse modulation systems, Sampling and quantization
Generation, Signal Space Diagram and detection of FSK
Direct Sequence Spread Spectrum (DSSS)
SLO-2 Double sideband Full carrier FM transmitter: Direct Method Pulse modulation systems, Sampling and quantization
Generation, Signal Space Diagram and detection of FSK
Direct Sequence Spread Spectrum (DSSS)
S-3
SLO-1 Double sideband Suppressed carrier FM transmitter: Indirect Method PCM systems Probability of Error for FSK Direct Sequence Spread Spectrum (DSSS)
SLO-2 Single sideband Suppressed carrier, VSB FM transmitter: Indirect Method Bandwidth of PCM, PCM TDM signal multiplexing, Limitations of PCM system
Probability of Error for FSK Code Division Multiple Access of DSSS
S 4-5
SLO-1 Lab-1: AM modulator and Demodulator Lab-4: Pre emphasis and De-emphasis Lab-7: DPCM and its Demodulation
Lab-10: QPSK Modulation and Demodulation
Lab-13: Mini Project SLO-2
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 28
S-6 SLO-1
Generation of AM waves: Linear method-Collector modulator
Classification of radio receiver, Functions and Characteristics of radio receiver
Data formatting Generation, Detection, Signal Space Diagram of PSK
Code Division Multiple Access of DSSS
SLO-2 Generation of AM waves: Linear method- Collector modulator
Tuned Radio Frequency receiver Data formatting Generation, Detection, Signal Space Diagram of PSK
OFDM Communication
S-7 SLO-1 Non-linear Modulation-Balanced Modulator Super-heterodyne receiver- AM Differential PCM (DPCM) Probability of Error for PSK OFDM Communication
SLO-2 Non-linear Modulation-Balanced Modulator Super-heterodyne receiver- AM Differential PCM (DPCM) Probability of Error for PSK OFDM Communication
S-8 SLO-1
Demodulation of AM waves : Linear diode detector
Super-heterodyne receiver- FM Delta modulation (DM) Generation, signal space diagram and detection of QPSK
Measures of Information
SLO-2 Demodulation of AM waves : Linear diode detector
Super-heterodyne receiver- FM Delta modulation (DM), Noise in DM Generation, signal space diagram and detection of QPSK
Measures of Information
S 9-10
SLO-1 Lab-2: DSB-SC modulator and demodulator
Lab-5: PAM,PPM,PWM modulation and demodulation
Lab-8: DM and its Demodulation Lab-11: DPSK Modulation and Demodulation
Lab-14: Model Practical Exam SLO-2
S-11 SLO-1 Frequency modulation, Types of FM Sources of Noise Demodulation and detection process Probability of Error for QPSK
Source encoding, Shannon’s Channel
capacity theorem
SLO-2 Narrow Band FM, Wide Band FM, Phase modulation
Sources of Noise Demodulation and detection process Probability of Error for QPSK
Shannon’s Channel capacity theorem
S-12 SLO-1 Generation of Narrowband FM Noise in AM (Envelope Detection),
Maximum likelihood receiver structure, Matched filter receiver
Generation, signal space diagram and
detection of π/4 QPSK Linear block codes
SLO-2 Generation of Narrowband FM Noise in AM (Envelope Detection), Maximum likelihood receiver structure, Matched filter receiver
Generation, signal space diagram and detection of π/4 QPSK Linear block codes
S-13 SLO-1
Demodulation of FM : Foster seely discriminator
Noise in FM Probability error of the Matched filter, Inter symbol interference, Eye pattern
Generation, signal space diagram and detection of QAM Cyclic codes
SLO-2 Demodulation of FM : Foster seely discriminator
Threshold effect, Pre-emphasis and De-emphasis
Probability error of the Matched filter, Inter symbol interference, Eye pattern
Generation, signal space diagram and detection of QAM Cyclic codes
S 14-15
SLO-1 Lab-3: FM Modulator and Demodulator
Lab-6: Pulse Code Modulation and Demodulation
Lab-9: PSK Modulation and Demodulation
Lab-12: BER performance analysis of various Modulation Schemes
Lab-15: University Practical Exam SLO-2
Learning Resources
1. Simon Haykin and Michael Moher, “Communication Systems,” 5th edition, John Wiley & Sons, 2013
2. Singh. R. P & Sapre. S. D, “Communication Systems: Analog & Digital,” 3rd edition, McGrawHill Education, Seventh Reprint, 2016.
3. Simon Haykin, “Communication Systems”, John Wiley & Sons, 4th Edition, 20008. 4. Bernard Sklar, “Digital Communication, Fundamentals and Application”, Pearson Education Asia,
2nd Edition, 2001
5. Taub & Schilling, “Principle of Communication Systems”, McGraw Hill Inc, 2nd Edition, 2003. 6. John G. Proakis, “Digital Communication”, McGraw Hill Inc, 5th Edition, 2008. 7. B.P. Lathi, “Modern Digital and Analog Communication System”, Oxford University Press, 3rd Edition, 2005. 8. Shu Lin, Daniel Costello, “Error control coding – Fundamentals and Applications”, Prentice Hall, Upper Saddle
River, NJ, 2nd Edition, 2004. 9. Lab Manual
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 29
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)#
Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
20% 20% 15% 15% 15% 15% 15% 15% 15% 15% Understand
Level 2 Apply
20% 20% 20% 20% 20% 20% 20% 20% 20% 20% Analyze
Level 3 Evaluate
10% 10% 15% 15% 15% 15% 15% 15% 15% 15% Create
Total 100 % 100 % 100 % 100 % -
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Mr. Anuj Kumar, Bombardier Transportation, Ahmedabad, [email protected] 1. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] Mrs. S. Vasanthadev Suryakala, SRMIST
2. Mr. Hariharasudhan - Johnson Controls, Pune, [email protected] 2. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected]
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 30
Course Code
18ECC206J Course Name
VLSI Design Course
Category C Professional Core
L T P C
3 0 2 4
Pre-requisite Courses
18ECC103J Co-requisite
Courses Nil
Progressive Courses
18ECE301J
Course Offering Department Electronics and Communication Engineering Data Book / Codes/Standards Nil
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Use Verilog HDL as a design-entry language for FPGA in electronic design automation of digital circuits 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
CLR-2 : Design, construct and simulate VLSI adders and multipliers.
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& C
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Indi
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Tea
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Com
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Pro
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Mgt
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Life
Lon
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Res
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CLR-3 : Understand MOSFET operation CLR-4 : Implement a given logic function using appropriate logic styles for improved performance
CLR-5 : Understand the basic processes in IC fabrication, steps in the fabrication of MOS ICs, and as well the layout design rules.
CLR-6 : Use modern engineering tools such as HSPICE / Modelsim / Xilinx to carry out design experiments and gain experience with the design and analysis of MOS circuits and systems.
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Design and implement digital circuits using Verilog HDL to simulate and verify the designs. 3 85 75 - H H - H - - - - - - - - - -
CLO-2 : Design general VLSI system components, adder cells and multipliers to address the design of datapath subsystem. 3 85 75 - H H - H - - - - - - - - - -
CLO-3 : Examine the characteristics of MOS transistors 2 80 70 H M - - - - - - - - - - - - -
CLO-4 : Analyze CMOS inverter and other complex logic gates designed using different logic styles 2 80 70 - L L - - - - - - - - - - - - CLO-5 : Explain how the transistors are built, and understand the physical implementation of circuits. 2 80 70 - L L - - - - - - - - - - - -
CLO-6 : Use HSPICE computer analysis program and Verilog HDL for simulation and analysis of MOS circuits and building blocks 3 85 75 - M M - H - - - H M L M - - M
Duration (hour)
Learning Unit / Module 1: Introduction to Verilog HDL & Coding
Learning Unit / Module 2: Subsystem Design
Learning Unit / Module 3: MOS Transistor
Learning Unit / Module 4: CMOS Inverter and Circuit Design
Styles
Learning Unit / Module 5:
15 15 15 15 15
S-1
SLO-1 Introduction to HDL & Verilog HDL General VLSI System Components: Multiplexers
Generic overview of the MOS device: MOS transistor symbols
CMOS Inverter Characteristics: Operation and properties of static CMOS inverter
Properties of basic materials used in microelectronics: Silicon, Silicon dioxide
SLO-2 Introduction to Verilog HDL, modules and ports
Decoders
MOS structure demonstrating (a) accumulation, (b) depletion, and (c) inversion; nMOS transistor demonstrating cutoff, linear, and saturation regions of operation
VTC of static CMOS inverter Polysilicon and Silicon Nitride
S-2 SLO-1
Lexical Conventions: White Space and Comments, Operators
Comparators MOS Transistor under Static Conditions: The threshold voltage
DC Inverter Calculations
Basic Processes in Integrated-Circuit Fabrication: Wafer Formation, Photolithography, Well and Channel Formation
SLO-2 Numbers, Strings, Identifiers, System Names, and Keywords
priority encoder Resistive operation Symmetrical Inverter Silicon Dioxide (SiO2), Isolation, Gate Oxide
S-3
SLO-1 Verilog Data Types: Nets, Register Variables, Constants
shift and rotate operations Saturation region Inverter switching characteristics Gate and Source/Drain Formations, Contacts and Metallization, Passivation, Metrology
SLO-2 Referencing Arrays of Nets or Regs Adders: Standard adder cells Current-voltage characteristics Output capacitance Some Recurring Process Steps: Diffusion and Ion Implantation, Deposition, Etching, Planarization
S-4, 5 SLO-1 Lab-0: Verilog Operators: Lab-6: Realization of VLSI multipliers - I
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 31
SLO-2
Arithmetic Operators, Bitwise Operators, Reduction Operators, Logical Operators, Relational Operators, Shift Operators, Conditional Operator, Concatenation Operator, Expressions and Operands, Operator Precedence
Lab-3: Design using FSM and ASM charts
Lab-9: Design and Analysis of CMOS Inverter using HSPICE
Lab-12: Design and Analysis of 4-input Dynamic NAND gate using HSPICE
S-6 SLO-1 Verilog modelling: Gate-level modelling Ripple Carry Adder (RCA)
Dynamic behavior: MOSFET Capacitances, viz., MOS structure capacitances
Secondary Parasitic Effects: Leakage Currents, Parasitic Resistances
Simplified CMOS Process flow
SLO-2 Realization of Combinational and sequential circuits
Carry Look-Ahead Adder (CLA) Channel capacitance and Junction (or, depletion) capacitances
Inverter layout
S-7 SLO-1
Compilation and simulation of Verilog code
Carry Select Adder (CSL) Parasitic Resistances, viz., Drain and Source Resistance, Contact Resistance
Power-Delay Product: Static Power Consumption
Layout design rules: Well rules, transistor rules
SLO-2 Test bench Carry Save Adder (CSA) Non-ideal I-V effects: Mobility Degradation, Velocity Saturation
Dynamic Power Consumption, Total Power Consumption, PDP
Contact rules, metal rules, via rules and other rules
S-8
SLO-1 Dataflow modelling Carry Skip Adder (CSK) Channel Length Modulation, Threshold Voltage Effects
CMOS Circuit Design Styles: Static CMOS logic styles
Gate Layouts
SLO-2 Realization of Combinational and sequential circuits
Carry Bypass Adder (CBA) Leakage, Temperature Dependence, Geometry Dependence, Subthreshold Current
CMOS circuits, pseudo-nMOS, tristate circuits, clocked CMOS circuits
Stick diagrams
S-9, 10
SLO-1 Lab-1: Realization of combinational and sequential circuits using gate-level and dataflow modeling
Lab-4: Realization of VLSI adders - I Lab-7: Realization of VLSI multipliers - II
Lab-10: (a) Design and Analysis of complex CMOS gate using HSPICE (b) Design and Analysis of Pseudo-NMOS gates using HSPICE
Lab-13: Model Practical Examination SLO-2
S-11 SLO-1 Behavioral modelling
Multipliers: Overview of multiplication (unsigned multiplication, shift/add multiplication algorithms, multiplication of signed numbers, types of multiplier architectures)
Short-channel MOSFETS: Hot carriers, Lightly-Doped Drain (LDD)
Differential Cascade Voltage Switch Logic (DCVSL), Pass Transistor Logic (PTL)
CMOS Process Enhancements: Transistors (Multiple Threshold Voltages and Oxide Thicknesses, Silicon-on-Insulator, High-k Gate Dielectrics, Higher Mobility, Plastic Transistors,)
SLO-2 Realization of Combinational and sequential circuits
Braun multiplier MOSFET scaling Dynamic CMOS logic styles: Basic dynamic logic
S-12
SLO-1 Switch-level modelling Baugh-Wooley multiplier Short-channel effects: Negative Bias Temperature Instability (NBTI), oxide breakdown
Signal integrity issues in dynamic design Interconnects
SLO-2 Realization of MoS circuits Wallace Tree multiplier Drain-Induced Barrier Lowering (DIBL), Gate-Induced Drain Leakage (GIDL), Gate Tunnel Current
Signal integrity issues in dynamic design Circuit elements
S-13 SLO-1 Design using FSM Booth multiplier Tutorials
Domino Logic Circuits: Differential Domino logic, multiple-output domino
Beyond conventional CMOS
SLO-2 Realization of sequential circuits Booth multiplier Tutorials Compound domino, NORA, TSPC Tutorials
S-14, 15
SLO-1 Lab-2: (a) Realization of digital circuits using behavioral modeling (b) Realization of MOS circuits using switch-level mdeling
Lab-5: Realization of VLSI adders - II Lab-8: Realization of RAM & ROM
Lab-11: (a) Design and Analysis of AND/NAND gate in DCVSL using SPICE (b) Design and Analysis of Pass-Transistor gates and CPL gates using HSPICE
Lab-14: End-Semester Practical Examination SLO-2
Learning Resources
1. Jan Rabaey, Anantha Chandrakasan, B Nikolic, “Digital Integrated Circuits: A Design Perspective”. Second Edition, Feb 2003, Prentice Hall of India.
2. Weste, Harris, “CMOS VLSI Design: A Circuits and Systems Perspective”, 4th edition, Addision-Wesley, 2011.
3. Wayne Wolf, “Modern VLSI Design: IP-based Design”, 4th edition, PHI, 2009.
4. R. Jacob Baker, “CMOS Circuit Design, Layout, and Simulation”, Wiley, (3/e), 2010. 5. John P. Uyemura, “CMOS Logic Circuit Design”, Kluwer, 2001. 6. S. Palnitkar , Verilog HDL – A Guide to Digital Design and Synthesis, Pearson , 2003 7. Paul. R.Gray, Robert G. Meyer, “Analysis and Design of Analog Integrated Circuits”, Wiley, (4/e), 2001. 8. M.D.Ciletti , Modeling, Synthesis and Rapid Prototyping with the Verilog HDL, Prentice Hall, 1999
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 32
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)# Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
20% 20% 15% 15% 15% 15% 15% 15% 15% 15% Understand
Level 2 Apply
20% 20% 20% 20% 20% 20% 20% 20% 20% 20% Analyze
Level 3 Evaluate
10% 10% 15% 15% 15% 15% 15% 15% 15% 15% Create
Total 100 % 100 % 100 % 100 % 100 %
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Mr. Anuj Kumar, Bombardier Transportation, Ahmedabad, [email protected] 1. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] 1. Mr. Manikandan AVM, SRMIST
2. Mr. Hariharasudhan - Johnson Controls, Pune, [email protected] 2. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected] 2. Dr. J. Manjula, SRMIST
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 33
Course Code
18ECC301T Course Name
WIRELESS COMMUNICATION Course
Category C Professional Core
L T P C
3 1 0 4
Pre-requisite Courses
18ECC205J, 18ECC105T Co-requisite
Courses Nil
Progressive Courses
18ECE220T
Course Offering Department Electronics and Communication Engineering Data Book / Codes/Standards Nil
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Understand the elements of Wireless Communication and mobile communications 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 CLR-2 : Understand the Mobile Radio Wave Propagation - Large Scale Fading
Leve
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Mod
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Too
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Soc
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ultu
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Env
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Sus
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abili
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Eth
ics
Indi
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Tea
m W
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Com
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Pro
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Mgt
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Life
Lon
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: Pro
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CLR-3 : Analyze how to apply Mobile Radio Wave Propagation - Small Scale Fading
CLR-4 : Study the Capacity and Diversity concepts in wireless communications
CLR-5 : Acquire the knowledge of Wireless System and Standards
CLR-6 : Understand and design various wireless systems
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Acquire the knowledge of Wireless communication and basic cellular concepts 2 75 60 H - - - - - - - - - - M M - L
CLO-2 : Understand` the essential Radio wave propagation and mobile channel models 2 75 60 H H H H - - - - - - - M M - H
CLO-3 : Familiarize about Various performance analysis of mobile communication system. 2 75 60 H H H - - - - - - - - - - - H
CLO-4 : Attain the knowledge of Diversity and capacity concepts 2 75 60 H H - - - - - - - - - - - - H
CLO-5 : Be familiar with the various standards of Mobile Communication Systems 2 75 60 H - - - - - - - - - - M M - L CLO-6 : Explore the various concepts of wireless communication, its design with respect to fading and link performance 2 75 60 H H H H M - - - - M - M M - H
Duration (hour)
Wireless communication: Mobile communications
Large Scale Fading Small Scale Fading Improvement on Link performance Wireless systems and standards
12 12 12 12 12
S-1 SLO-1
Introduction to wireless communication and mobile radio communication
Introduction to Radio wave Propagation Introduction Small scale multipath propagation Introduction to diversity, equalization and
capacity AMPS Voice modulation Process
SLO-2 Classification of wireless communications - simplex, half duplex, dull duplex
Large scale and small scale fading Impulse response model of multipath channel
S-2 SLO-1 Paging and Cordless systems
Friis transmission equation- Free space propagation model - pathloss model
Impulse response model of multipath channel
Space diversity GSM system architecture and its interfaces
SLO-2 Cellular telephone systems Small scale multipath measurements - Direct Pulse measurement
Scanning diversity
S-3 SLO-1 Timing diagram - landline to mobile
Two Ray model
Small scale multipath measurements - Sliding correlator measurement
Maximal ratio combiner GSM frame structure
SLO-2 Timing diagram - mobile to mobile Small scale multipath measurements - Swept frequency measurement
Equal gain diversity
S-4 SLO-1
Basic antenna parameters, Far field and near field
Simplified pathloss model Parameters of mobile multipath channels - Time dispersion and Coherent bandwidth
Rake Receiver GSM speech operations input - output SLO-2
Frequency reuse, sectored and omni-directional antennas
Emperical model - Okumara
S-5 SLO-1 Channel assignment strategies Emperical model - Hata model
Parameters of mobile multipath channels - Doppler spread and Coherent time
Capacity in AWGN Forward CDMA process SLO-2 Handoff and its types
Emperical model - Walfish and bertoni model
S-6 SLO-1
Interference and system capacity Piecewise linear model - log normal model Types of fading: Flat and Frequency selective fading
Capacity of flat fading channels
Reverse CDMA Process SLO-2
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 34
S-7 SLO-1
Trunking and Grade of Service Shadowing Types of fading: Flat and Frequency
selective fading Equalizer and its mode Multicarrier modulation
SLO-2 Combined pathloss and shadowing
S-8 SLO-1 Cell splitting
Outage Probabilty Types of fading: Fast and Slow fading Adaptive equalizer block diagram OFDM Transmitter Block diagram
SLO-2
S-9 SLO-1
Sectoring Cell Coverage Area Types of fading: Fast and Slow fading Types of Equalizers - elementary level only OFDM Receiver Block diagram SLO-2
S-10 SLO-1 Microcell zone concepts
Solving problems – Brewster angle Ricean distribution Introduction to MIMO antennas Importance of Cyclic Prefix
SLO-2
S-11 SLO-1
Umbrella cells Solving problems –empirical model Rayleigh distribution Introduction to MIMO antennas Case study - Modern antennas SLO-2
S-12 SLO-1
Solving Problems Solving problems – friis transmission formula
Solving problems – Doppler effect Case study :Recent trends in Diversity and MIMO antennas
Case study - Modern antennas SLO-2
Learning Resources
1. Rappaport.T.S., ”Wireless Communications: Principles and Practice”, 2nd Edition, Pearson, 2011. 2. John D Kraus , Ronald J Marhefka, Ahmed S Khan “Antenna and Wave Propagation”, 4th Edition, Tata
McGraw Hill, 2010 3. Constantine Balanis. A, “Antenna Theory: Analysis and Design”, 3rd Edition, John Wiley, 2012. 4. Andreas.F.Molisch., "Wireless Communications", Wiley, 2nd Edition-2005, Reprint-2014
5. Andrea Goldsmith, “ Wireless Communications”, Cambridge University Press, Aug 2005 6. Schiller, "Mobile Communications", Pearson Education Asia Ltd., Reprint 2012 7. Lee W.C.Y., " Mobile Communications Engineering: Theory and Applications", McGraw Hill, New York,
2nd Edition, 1998
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)#
Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
40 % - 30 % - 30 % - 30 % - 30% - Understand
Level 2 Apply
40 % - 40 % - 40 % - 40 % - 40% - Analyze
Level 3 Evaluate
20 % - 30 % - 30 % - 30 % - 30% - Create
Total 100 % 100 % 100 % 100 % 100 % # CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers
Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Mr. Anuj Kumar, Bombardier Transportation, Ahmedabad, [email protected] 1. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] 1. Dr. Sandeep Kumar P, SRMIST
2. Mr. Hariharasudhan - Johnson Controls, Pune, [email protected] 2. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected] 2. Dr. T. Ramarao, SRMIST
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 35
Course Code
18ECC302J
Course Name
MICROWAVE & OPTICAL COMMUNICATIONS Course
Category C Professional Core
L T P C
3 0 2 4
Pre-requisite Courses
18ECC205J Co-requisite
Courses Nil
Progressive Courses
18ECE226T & 18ECE323T
Course Offering Department Electronics and Communication Engineering Data Book / Codes/Standards Nil
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Identify Microwave active devices and Microwave generators 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
CLR-2 : Analyze Microwave passive devices
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Sus
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CLR-3 : Explore Microwave Measurements
CLR-4 : Analyze Optical Fibers Optical Sources, Amplifier and Transmitter Optical Detectors , Receiver and Performance Measurements
CLR-5 : Explore Optical Communication System Design and Concepts
CLR-6 : Analyze Microwave and optical components
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Acquire knowledge on the theory of microwave transmission, microwave generators and associated components. 2 80 70 H - - L - - - - - - - - - - L
CLO-2 : Analyse microwave passive devices and components. 2 80 70 H M H H - - - - - - - - L - M
CLO-3 : Understand microwave measurements and associated techniques with equipment 2 80 70 H M H M - - - - - - - - M - H
CLO-4 : Familiarize with the fundamentals of light transmission through fiber 2 80 70 H H - M - - - - - - - - L - L
CLO-5 : Design a basic optical communication system. 2 80 70 H H - H - - - - - - - - M - M
CLO-6: Understand the working principle of microwave components , Microwave measurements, optical sources, detector and fibers
2 80 70 H H H H - - - - - - - - M - H
Duration (hour)
15 15 15 15 15
S-1 SLO-1 Introduction to microwaves and optical
communications
High frequency parameters: S parameters and S matrix analysis for N-port microwave device
Impedance matching. Elements of Optical fiber communication Point-to-Point link –Analog system design considerations and design steps SLO-2
S-2 SLO-1 History of Microwave Engineering,
Microwave transmission and Applications; Maxwell Equations
Directional coupler VSWR and Impedance measurement Functional block diagram of a Transmitter and receiver module
Point-to-Point link – Digital system design considerations and design steps SLO-2
S-3 SLO-1 Microwave Tubes
E and H plane Tee Measurement of Power Optical fiber structure, Light Propagation in Optical fibers: Ray theory , Total Internal reflection, Skew rays
Digital Link Design: Link power budget SLO-2 Klystron amplifier
S-4-5 SLO-1
Lab- 1 Characteristics of Reflex Klystron
Lab- 4 Gain and radiation pattern of Horn antenna
Lab- 7 Practice session Lab- 10 Measurement of Numerical Aperture, propagation and bending losses of optical fiber
Lab- 13 Design of basic Optical Communication system using computational tool SLO-2
S-6 SLO-1
Reflex Klystron oscillators Magic Tee Measurement of Frequency and Q factor Optical Sources: Light source materials, LED Structures
Rise time budget SLO-2
S-7 SLO-1
Magnetron oscillators Microwave Circulators, Isolators Insertion loss measurements LED Characteristics Overview of Analog links: Radio over Fiber; SLO-2
S-8 SLO-1 Microwave Bipolar Transistors
Field effect transistor Attenuators and Phase Shifters Attenuation measurements
Semiconductor Laser Diode, Laser Characteristics
Key link parameters SLO-2
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 36
S-9-10
SLO-1 Lab- 2 Study of power distribution in Directional coupler, E plane, H plane and Magic Tee
Lab- 5 Characteristics of filters, Microstrip patch antenna and parallel line coupler
Lab- 8 DC characteristics of LED and Laser diode
Lab- 11 Analysis of Analog optical link Lab- 14 Practice Session SLO-2
S-11 SLO-1
IMPATT, TRAPATT and Tunnel diode Rectangular Waveguides Measurement of Scattering parameters Optical Detectors: PIN and APD photo detector
Multichannel System: Need for multiplexing
SLO-2 Operational principles of WDM, DWDM
S-12 SLO-1
Gunn diode Rectangular Waveguides Measurement of Scattering parameters Responsivity and efficiency of APD WDM Components: Coupler/Splitter, Fabry Perot Filter SLO-2
S-13 SLO-1
Gunn Oscillation modes Power Dividers Functioning details of Vector Network Analyzer; Signal Analyzer; Spectrum analyzers
Fiber attenuation and dispersion WDM Components: Optical MEMS switches SLO-2
S-14-15
SLO-1 Lab- 3 Impedance measurement by slotted line method
Lab- 6 Design of RF Filters and Amplifier using computational tool
Lab- 9 DC characteristics of PIN and APD photo-diode
Lab- 12 Analysis of Digital optical link Lab- 15 Study experiment - Gunn Diode (Microwave) and Optical WDMA (Optical) SLO-2
Learning Resources
1. David M. Pozar, “Microwave Engineering”, 4th Edition, John Wiley & Sons, 2012. 2. David M. Pozar, “Microwave & RF Design of Wireless Systems”, John Wiley & Sons, 2001. 3. Samuel Y. Liao, “Microwave Devices and Circuits”, 3rd Edition, Pearson Education, 2013. 4. Robert. E. Collin, “Foundations for Microwave Engineering”, 2nd edition, Wiley, Reprint 2014. 5. Annapurna Das, Sisir K. Das, “Microwave Engineering”, 3rd Ed., McGraw Hill, 2015. 6. I. Hunter, “Theory and design of microwave filters”, The Institution of Engineering &Technology,
2001. 7. Keiser G, “Optical Fiber Communication Systems”, 5th Edition, 6th Reprint, McGraw Hill
Education (India), 2015.
8. Vivekanand Mishra, Sunita P. Ugale, “Fiber Optic Communication: Systems and Components”, Wiley-India, 1st edition, 2013
9. Djafar.K. Mynbaev and Lowell and Scheiner, “Fiber Optic Communication Technology”, Pearson Education Asia, 9th impression, 2013
10. John M. Senior, “ Optical fiber Communications: Principles and Practice”, Pearson Education, 3rd Edition, 2009
11. R.P. Khare, “Fiber Optics and Optoelectronics”, Oxford University Press, 2007. 12. 12. Rajiv Ramaswami, Kumar N. Sivaranjan, Galen H.Sasaki "Optical Networks A practical perspective",
3nd edition, 2013
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)# Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
20% 20% 15% 15% 15% 15% 15% 15% 15% 15% Understand
Level 2 Apply
20% 20% 20% 20% 20% 20% 20% 20% 20% 20% Analyze
Level 3 Evaluate
10% 10% 15% 15% 15% 15% 15% 15% 15% 15% Create
Total 100 % 100 % 100 % 100 % 100 %
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers
Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Mr. Anuj Kumar, Bombardier Transportation, Ahmedabad, [email protected] 1. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] 1. Dr. P. Sandeep Kumar, SRMIST
2. Mr. Hariharasudhan - Johnson Controls, Pune, [email protected] 2. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected] 2. Dr. T. Ramarao, SRMIST
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 37
Course Code
18ECC303J Course Name
COMPUTER COMMUNICATION NETWORKS Course
Category C Professional Core
L T P C
3 0 2 4
Pre-requisite Courses
18CSS101J Co-requisite
Courses Nil
Progressive Courses
18ECE320T
Course Offering Department Electronics and Communication Engineering Data Book / Codes/Standards Nil
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Introduce the basic concepts in the field of computer networks. 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 CLR-2 : Understand the functional aspects of OSI model architecture.
Leve
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Exp
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ienc
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)
Exp
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d A
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men
t (%
)
Eng
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ring
Kno
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Pro
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Ana
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Des
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& D
evel
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s, D
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n, R
esea
rch
Mod
ern
Too
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ge
Soc
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& C
ultu
re
Env
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ent &
Sus
tain
abili
ty
Eth
ics
Indi
vidu
al &
Tea
m W
ork
Com
mun
icat
ion
Pro
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Mgt
. & F
inan
ce
Life
Lon
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arni
ng
PS
O–1
: Pro
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iona
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Ach
ieve
men
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: Pro
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Man
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CLR-3 : Acquire knowledge of the Network Layer protocols
CLR-4 : Analyze the various issues and challenges of Transport Layer.
CLR-5 : Familiarize the various Application Layer Protocols.
CLR-6: Utilize the networking concepts to analyze the performance of Routing protocols.
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Express the basic services and concepts related to internetworking. 1 60 65 - - - - - - H - - - - M - - -
CLO-2 : Explain the basic OSI model architecture and its lower layer functions. 1 60 65 - - M - - - L - - - - - - - H
CLO-3 : Illustrate the various Network Layer concepts, mechanisms and protocols. 2 65 65 - - H - - L M - - - - - - - -
CLO-4 : Describe the services and techniques of Transport Layer. 1 60 65 - - - - - - M - - - - - - - H
CLO-5 : Discuss the various services and protocols in Application Layer. 1 60 65 - - M - - - - - - - - - - - H CLO-6 : Analyze the various Networking concepts and Routing protocols. 2 60 65 - - - - L - - - - - - M - - H
Duration (hour)
DATA COMMUNICATION & NETWORKING BASICS
OSI LOWER LAYERS
NETWORK LAYER TRANSPORT LAYER APPLICATION LAYER
15 15 15 15 15
S-1 SLO-1
Introduction to Data Communication and Networking
Network models Introduction to Network Layer Introduction to Transport Layer Introduction to Application Layer
SLO-2 Data transfer modes-Serial and Parallel transmission
OSI layer architecture Need for Internetworking TCP/IP Model Application Layer Paradigms
S-2 SLO-1 Protocols & Standards Data Link Layer-Introduction Addressing-Classful User Datagram Protocol(UDP) Client Server Interaction
SLO-2 Layered Architecture Link Layer Addressing Addressing-Classful User Datagram Protocol(UDP) Client Server Interaction
S-3 SLO-1 Principles of Layering & Description Error Detection Addressing-Classless Transmission Control Protocol(TCP) SIP
SLO-2 Brief description of concepts in OSI & TCP/IP model
Error Detection Addressing-Classless Transmission Control Protocol(TCP) SIP
S 4-5
SLO-1 Lab 1: To build and configure a simple network of four nodes connected with point-to-point links.
Lab 4: To simulate token ring protocol and to study its performance.
Lab 7:To simulate CSMA/CA protocol and to study its performance
Lab 10: Implementation and study of Selective Repeat protocol.
Lab 13: Create a Socket (TCP&UDP) between two computers and enable file transfer between them. SLO-2
S-6 SLO-1
Switching Types- Circuit- & Packet switching
Error Correction Network Layer Protocol-IPV4 TCP Services & Features Compression Techniques
SLO-2 Switching Types- Message switching, Comparison of switching types
Error Correction Internet Protocol(IP)-IPV4 TCP Services & Features Compression Techniques
S-7 SLO-1 LAN, MAN & WAN Data link control-LLC Internet Protocol(IP)-IPV6 Congestion Control Introduction to Cryptography
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 38
SLO-2 LAN, MAN & WAN Data link control-LLC Internet Protocol(IP)-IPV6 Congestion Control Types, Attacks and Services
S-8 SLO-1 Network topologies-Types Data link control-MAC
Routing Protocols- Distance Vector& Link State
Congestion Control DES
SLO-2 Comparison of topologies Data link control-MAC Routing Issues-Delivery, Forwarding and Routing
Congestion Control DES
S 9-10
SLO-1 Lab 2: To simulate star and bus network topologies.
Lab 5: Implementation of Error detection and Correction scheme.
Lab 8: Implementation and study of stop and wait protocols
Lab 11: To configure a network using Link State Routing protocol .
Lab 14: Implementation of Data Encryption and Decryption. SLO-2
S-11 SLO-1 IEEE standards for LAN-Ethernet Flow & Error Control Protocol Routing Information Protocol-RIP QOS-Quality of Service RSA
SLO-2 Types of Ethernet Flow & Error Control Protocol Routing Information Protocol-RIP QOS-Quality of Service RSA
S-12 SLO-1 Token Bus ARQ Schemes Open Shortest Path First-OSPF Techniques to improve QOS Email
SLO-2 Token Ring ARQ Schemes Open Shortest Path First-OSPF Techniques to improve QOS FTP
S-13 SLO-1 FDDI HDLC Border Gateway Protocol-BGP Techniques to improve QOS HTTP
SLO-2 FDDI HDLC Border Gateway Protocol-BGP Techniques to improve QOS SNMP
S 14-15
SLO-1 Lab 3: To simulate token bus protocol and to study its performance.
Lab 6:To simulate CSMA/CD protocol and to study its performance
Lab 9: Implementation and study of Go back N protocol.
Lab 12: To configure a network using Distance Vector Routing protocol.
Lab 15: Mini Project SLO-2
Learning Resources
1. Behrouz A.Fehrouzan, “Data communication & Networking”, Mc-Graw Hill, 5th Edition Reprint, 2014.
2. Andrew S.Tanenbaum, “Computer Networks”, Pearson Education India, 5th Edition, 2013.
3. William Stallings, “Data & Computer Communication”, Pearson Education India, 10th Edition, 2014. 4. James F. Kurose, Keith W. Ross, “Computer Networking: A Top–Down Approach Featuring the Internet”,
Pearson Education,6th Edition, 2013. 5. “Lab Manual” , Department of ECE, SRM Institute of Science and Technology
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)#
Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
20% 20% 15% 15% 15% 15% 15% 15% 15% 15% Understand
Level 2 Apply
20% 20% 20% 20% 20% 20% 20% 20% 20% 20% Analyze
Level 3 Evaluate
10% 10% 15% 15% 15% 15% 15% 15% 15% 15% Create
Total 100 % 100 % 100 % 100 % 100 %
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers
Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Mr. Anuj Kumar, Bombardier Transportation, Ahmedabad, [email protected] 1. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] 1. Ms. T. Ramya, SRMIST
2. Mr. Hariharasudhan - Johnson Controls, Pune, [email protected] 2. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected]
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 39
Course Code
18ECC350T Course Name
COMPREHENSION Course
Category C Professional Core
L T P C 0 1 0 1
Pre-requisite Courses
NIL Co-requisite
Courses NIL Progressive Courses NIL
Course Offering Department Electronics and Communication Engineering Data Book / Codes/Standards Nil
Course Learning Rationale (CLR):
The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Acquire skills to solve real world problems in Analog and Digital Electronics (Discrete & IC) 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
CLR-2 : Acquire skills to solve real world problems in Analog and Digital Communication
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CLR-3 : Acquire skills to solve real world problems in Signals & Systems, and DSP
CLR-4 : Acquire skills to solve real world problems in Microprocessors & Microcontrollers, and VLSI Design
CLR-5 : Acquire skills to solve real world problems in Electromagnetics and Transmission Lines
CLR-6 : Acquire skills to solve real world problems in Microwave and Optical Communications
Course Learning Outcomes (CLO):
At the end of this course, learners will be able to:
CLO-1 : Practice and gain confidence and competence to solve problems in Analog and Digital Electronics (Discrete & IC) 3 85 80 H H H L L L L L L L L L M L M
CLO-2 : Practice and gain confidence and competence to solve problems in Analog and Digital Communication 3 85 80 H H M L L L L L L L L L M M M
CLO-3 : Practice and gain confidence and competence to solve problems in Signals & Systems, and DSP 3 85 80 H H M L L L L L L L L L M L M
CLO-4 : Practice and gain confidence and competence to solve problems in Microprocessors & Microcontrollers, and VLSI Design 3 85 80 H H M L L L L L L L L L M M M
CLO-5 : Practice and gain confidence and competence to solve problems in Electromagnetics and Transmission Lines 3 85 80 H H H L L L L L L L L L M L M CLO-6 : Practice and gain confidence and competence to solve problems in Microwave and Optical Communications 3 85 80 H H M L L L L L L L L L M M M
Duration (hour) 3 3 3 3 3
S-1 SLO-1
Tutorial on Analog Electronics (Discrete & IC)
Tutorial on Digital Communication Tutorial on Microprocessors & Interfacing
Tutorial on Transmission Lines Tutorial on Optical Communication
SLO-2 Problem Solving Problem Solving Problem Solving Problem Solving Problem Solving
S-2 SLO-1 Tutorial on Digital Electronics Tutorial on Signals and Systems
Tutorial on Microcontrollers & Interfacing
Tutorial on VLSI Design Model Test
SLO-2 Problem Solving Problem Solving Problem Solving Problem Solving Model Test
S-3 SLO-1 Tutorial on Analog Communication Tutorial on Digital Signal Processing Tutorial on Electromagnetics Tutorial on Microwave Communication Final Test
SLO-2 Problem Solving Problem Solving Problem Solving Problem Solving Final Test
Learning Resources
1. R.S.Khurmi, J.K.Gupta, Mechanical Engineering: Conventional and Objective Types, S.Chand & Co., 2018
2. R.K.Jain, Conventional & Objective Type Question & Answers on Mechanical Engineering for Competitions, Khanna Publishers, 2014
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)#
Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
- 40% - 30% - 30% - 30% - 30% Understand
Level 2 Apply
- 40% - 40% - 40% - 40% - 40% Analyze
Level 3 Evaluate
- 20% - 30% - 30% - 30% - 30% Create
Total 100 % 100 % 100 % 100 % 100 %
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 40
Course Designers
Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Mr. Anuj Kumar, Bombardier Transportation, Ahmedabad, [email protected] 1. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] Mr. Manikandan AVM, SRMIST
2. Mr. Hariharasudhan - Johnson Controls, Pune, [email protected] 2. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected] Dr. V. Nithya, SRMIST
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 41
B. Tech in Electronics and Communication Engineering (with specialization in Cyber Physical System)
2018 Regulations
Professional Elective Courses (E)
Department of Electronics and Communication Engineering SRM Institute of Science and Technology
SRM Nagar, Kattankulathur – 603203, Kancheepuram District, Tamilnadu
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 42
Course Code
18ECE250T Course Name
PRINCIPLES OF CYBER PHYSICAL SYSTEM Course
Category E Professional Elective
L T P C
3 0 0 3
Pre-requisite Courses
18MAB101T Co-requisite
Courses NIL
Progressive Courses
NIL
Course Offering Department Electronics and Communication Data Book / Codes/Standards NIL
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Obtain cyber physical systems fundamentals and principles knowledge as building blocks to promote further design and implementation of more complex real time systems.
1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
CLR-2 : Understand cyber physical systems design for synchronous model with specific case study for arm processor.
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CLR-3 : In what way cyber physical systems are crucial for the optimal performance of asynchronous model.
CLR-4 : Comprehend the cyber physical systems design and implementation in dynamical models.
CLR-5 : Hybridization of cyber physical systems which will help the students to anticipate upcoming technologies.
CLR-6 : Gain overall understand of the cyber physical systems for that will suit practical, engineering and industrial needs.
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Understand the basics of cyber physical systems. 1 90 75 H - - - - - - - - - - - - - -
CLO-2 : Design synchronous models for Real Time applications. 1 80 70 H - - - - - - - - - - - - - -
CLO-3 : Design Asynchronous models for Real Time applications. 2,3 90 75 - M H - H - - - - - - - - - -
CLO-4 : Develop Deep Understanding on selection of hardware and software’s for designing dynamical systems. 2,3 90 75 - M H - H - - - - - - - - - -
CLO-5 : Come up with cost effective, reliable, robust and feasible designs for real world problems. 2 80 75 - M H - L - - - - - - - - - -
CLO-6 : Design and implement cyber physical system and address the problems and limitations for real world problems. 2 90 75 - M H - H - - - H - - - M - L
DURATION (HOUR)
INTRODUCTION TO CYBER PHYSICAL SYSTEMS
SYNCHRONOUS MODEL ASYNCHRONOUS MODEL DYNAMICAL SYSTEM HYBRID SYSTEMS
S-1 SLO-1 Introduction To Cyber-Physical Systems Reactive Components Asynchronous Process Continuous Time Model Hybrid Dynamical Model
SLO-2 Cyber-Physical Systems Design Recommendations.
Variables, Valuations, And Expression States, Internal Actions Continuously Evolving Inputs And Outputs Hybrid Process, Process Composition
S-2 SLO-1 Cyber-Physical System Requirements Execution, Extended-State Machines Executions, Extended State Machines Continuously Evolving Inputs And Outputs Zeno Behavior
SLO-2 Requirements Engineering Properties Of Components Operation On Process Models With Disturbance Stability
S-3 SLO-1 Interoperability Finite State Components Asynchronous Design Primitives Composing Components Stability Designing Hybrid Systems
SLO-2 Real Time System Combinational Components Blocking Vs Non-Blocking Synchronization Composing Components Stability Automated Guided Vehicle
S-4 SLO-1 GPU Computing Event-Triggered Components Deadlocks Linear Systems Linearity Automated Guided Vehicle
SLO-2 Internet Of Things (IOT) Nondeterministic Components Deadlocks Linear Systems Linearity Obstacle Avoidance With Multi Robot Coordination
S-5
SLO-1 Internet Of Things (IOT) Input Enabled Components Shared Memory Solutions Of Linear Differential Equations Stability
Obstacle Avoidance With Multi Robot Coordination
SLO-2 Radio Frequency Identification Technology Task Graphs And Await Dependencies
Fairness Assumptions Solutions Of Linear Differential Equations Stability
Multi Hop Control Networks
S-6 SLO-1 Wireless Sensor Networks Technology Composing Components Asynchronous Coordination Protocols Designing Controllers Multi Hop Control Networks
SLO-2 Powerline Communication Block Diagrams Input / Output Variable Renaming
Asynchronous Coordination Protocols Open Loop Vs Feedback Controller Linear Hybrid Automata
S-7 SLO-1 Smart Cities And Internet Of Everything Parallel Composition Leader Election Stabilizing Controller Example Pursuit Game
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 43
SLO-2 Ubiquitous Computing Fundamentals Output Hiding Reliable Transmission Stabilizing Controller Example Pursuit Game
S-8 SLO-1 Core Properties Of Ubiquitous Computing Synchronous Designs Wait Fee Consensus PID Controllers Formal Model
SLO-2 Smart Devices: Components And Services Synchronous Circuits Safety Specifications Analysis Techniques Symbolic Reachability Analysis
S-9 SLO-1
Autonomous Systems In Ubiquitous Computing
Cruise Control Systems Invariants Of Transition Systems Numerical Solutions Timed Automata
SLO-2 CASE STUDY: Cyber Physical Vehicle Tracking System
Synchronous Networks Safety Monitors Barrier Certificates Model Of Timed Automata
Learning Resources
1. Rajeev Alur, Principles Of Cyber Physical Systems, 1st Edition, MITPress 2015. 2. Raj Rajkumar , “Cyber Physical Systems,” 2nd Edition, Elsevier 2015 3. Edward D Lamie, “Computing Fundamentals Of Cyber Physical Systems ” , 2nd Edition, Newnes Elsevier
Publication.
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)#
Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
40 % - 30 % - 30 % - 30 % - 30% - Understand
Level 2 Apply
40 % - 40 % - 40 % - 40 % - 40% - Analyze
Level 3 Evaluate
20 % - 30 % - 30 % - 30 % - 30% - Create
Total 100 % 100 % 100 % 100 % 100 %
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers
Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Mr. Athif Shah, Chairman, Abe Semicondutor, [email protected] 1. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] 1. Dr. Vivek Maik, SRMIST
2. Dr. Madan Kumar Lakshmanan, Senior Scientist, CEERI, [email protected] 2. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected]
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 44
Course Code
18ECE251T Course Name
EMBEDDED AND IMPLANTED DEVICES FOR CYBER PHYSICAL SYSTEM Course
Category E Professional Elective
L T P C
3 0 0 3
Pre-requisite Courses
18EES101J Co-requisite
Courses NIL
Progressive Courses
NIL
Course Offering Department Electronics and Communication Data Book / Codes/Standards NIL
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Understand the various embedded processors and memory architecture 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
CLR-2 : Identify suitable hardware and software available to develop a CPS
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CLR-3 : Study the multitasking and threading techniques for embedded processors
CLR-4 : Analyze the implementation scheme of implantable CPS for health care application
CLR-5 : Use Cyber physical systems for energy management
CLR-6 : Develop framework to put Human in CPS loop
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Identify suitable embedded processor and memory for cyber physical system applications 2,3 70 70 L M H - - - - - - - - - - - -
CLO-2 : Select optimal hardware and software for cyber physical system model 2,3 70 70 L M H - - - - - - - - - - - -
CLO-3 : Efficiently use the embedded processor resources 2,3 70 70 L M H - - - - - - - - - - - -
CLO-4 : Develop implantable CPS model for health care application. 2,3 70 70 L M H - - - - - - - - - - - -
CLO-5 : Develop implantable CPS model for various real world problems. 2,3 70 70 L M H - - - - - - - - - - - -
CLO-6 : Understand the realistic constraints to put concepts of Human in CPS loop in real time applications 3 90 80 - - H - M - - - M - - M H L -
Duration (hour)
EMBEDDED PROCESSORS INPUT AND OUTPUT HARDWARE AND
SOFTWARE MULTITASKING AND SCHEDULING
IMPLANTED CYBER-PHYSICAL SYSTEMS
HUMAN-IN-THE-LOOP CYBER-PHYSICAL SYSTEMS
S-1 SLO-1
Processors - Generalized Architecture Hardware - Pulse Width Modulation, Multitasking -Threads, Creating Threads,
Medical Cyber-Physical Systems - System Description And Operational Scenarios,
Theory Of HITLCPSS ,
SLO-2 Implementing Threads Virtual Medical Devices Data Acquisition
S-2 SLO-1 Processors – Speed General-Purpose Digital I/O Mutual Exclusion, Deadlock
Clinical Scenarios, Key Design Drivers And Quality Humans As Sets Of Sensors
SLO-2 Processors –Computational Power General-Purpose Digital I/O Memory Consistency Models Attributes, Trends
S-3 SLO-1 Microcontrollers - Architecture
Serial Interfaces The Problem With Threads Quality Attributes
Humans As Communication Nodes SLO-2 Microcontrollers Processes And Message Passing Challenges Of The MCPS Domain
S-4 SLO-1 DSP Processors- Architecture
Parallel Interfaces Scheduling - Basics Of Scheduling On-Demand Medical Devices State Inference, Human Nature
SLO-2 DSP Processors- Features Scheduling Decisions Assured Safety, Humans As Processing Nodes
S-5 SLO-1
Programmable Logic Controllers - Architecture Buses
Task Models, Smart Alarms And Clinical Decision Support Systems Humans And Robots As Actuators
SLO-2 Programmable Logic Controllers- Features Comparing Schedulers Closed-Loop System
S-6 SLO-1 Graphics Processors Architecture Software - Sequential Software In A
Concurrent World
Implementation Of A Scheduler Energy Cyber-Physical Systems - System Description Technologies For Supporting HITLCPS
SLO-2 Graphics Processors Architecture Rate Monotonic Scheduling Operational Scenarios
S-7 SLO-1 Parallelism, Pipelining, Interrupts Earliest Deadline First, Scheduling
Architecture HITL In Industry And At Home
SLO-2 Instruction-Level Parallelism Exceptions Mutual Exclusion HITL In Healthcare
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 45
S-8 SLO-1 Multicore Architectures Timers
Priority Inversion, Priority Inheritance Protocol Cyber Paradigm For Sustainable Sees
Social Networking
SLO-2 Multicore Architectures Atomicity Priority Ceiling Protocol Social Networking
S-9 SLO-1
Memory Architectures - Memory Technologies
Interrupt Controllers Multiprocessor Scheduling Practitioners’ Implications The Sample App’s Base Architecture
SLO-2 Memory Hierarchy, Memory Models Modeling Interrupts Scheduling Anomalies
Learning Resources
1. E. A. Lee And S. A. Seshia, Introduction To Embedded Systems - A Cyber-Physical Systems Approach, Second Edition, Mit Press, 2017.
2. Houbing Song Danda Rawat Sabina Jeschke Christian Brecher, Cyber-Physical Systems Foundations, Principles And Applications, , 1st Edition, Academic Press, 2016
3. Raj Rajkumar, Dionisio De Niz, Mark Klein, Cyber-Physical Systems, Pearson Education, Inc.2017,
4. David Nunes, Jorge Sá Silva, Fernando Boavida, A Practical Introduction To Human-In-The-Loop Cyber-Physical Systems, Johnwiley & Sons Ltd, 2018.
5. Raj Kamal, Internet Of Things, Mcgraw Hill Education; First Edition, 2017. 6. Edward Ashford Lee, Sanjit Arunkumar Seshia, Introduction To Embedded Systems - A Cyber Physical
Systems Approach - Second Edition, Lulu Enterprises Incorporated, 2014 7. Hamid R. Arabnia, Leonidas Deligiannidis, Fernando G. Tinetti, Embedded Systems, Cyber-Physical
Systems, And Applications, The 2017 Worldcomp International Conference Proceedings, Csrea, 2018
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)#
Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
40 % - 30 % - 30 % - 30 % - 30% - Understand
Level 2 Apply
40 % - 40 % - 40 % - 40 % - 40% - Analyze
Level 3 Evaluate
20 % - 30 % - 30 % - 30 % - 30% - Create
Total 100 % 100 % 100 % 100 % 100 %
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers
Experts from Industry Experts from Higher Technical Institutions Internal Experts
Dr. Vinay Kumar Gupta, National Physical Laboratory, [email protected] Prof .C. Vijayan, IITM, Chennai, [email protected] Dr. P. Eswaran, SRMIST
Prof. S. Balakumar, Univ of Madras, [email protected] Mr. A V M Manikandan, SRMIST
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 46
Course Code
18ECE252T Course Name
SENSORS AND ACTUATORS FOR CYBER PHYSICAL SYSTEM Course
Category E Professional Elective
L T P C
3 0 0 3
Pre-requisite Courses
18EES101J Co-requisite
Courses NIL
Progressive Courses
NIL
Course Offering Department Electronics and Communication Data Book / Codes/Standards NIL
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Learn sensor basic working 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
CLR-2 : Understand sensor design for embedded applications
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CLR-3 : Design optimal real time models and learn the uncertainties
CLR-4 : Understand the Interface of Sensor System Design And Implementation
CLR-5 : Develop Deep Understanding On Sensor Materials and Technologies
CLR-6 : Understand about industry grade sensors and applications
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Understand the working, classification and design of systems with sensors 1 60 70 - H - - L - - - - - - - - -
CLO-2 : Design multi sensor cyber physical system for real world applications 2 60 70 M - - - - - - - - - M - - -
CLO-3 : Implement different practical real time systems with minimal supervision 3 60 70 - M H - H - - - - - - - - L
CLO-4 : Develop Deep Understanding on selection of hardware and software’s for designing systems 1 60 70 - M - - - - - - - - H - - -
CLO-5 : Come up with cost effective, reliable, robust and feasible designs for real world problems 3 60 70 - M M - H - - - - H - - - H
CLO-6 : Design and implement real time systems and address the problems and limitations 3 60 70 - - M - H - - - - - H L - M
DURATION (HOUR)
SENSOR BASIC BLOCKS OPTICAL COMPONENTS OF SENSOR HUMAN DETECTORS CHEMICAL AND BIOLOGICAL
SENSORS MATERIALS AND TECHNOLOGIES
S-1 SLO-1 Data Acquisition Energy Of Light Quanta Ultrasonic Detectors Chemical Sensors Silicon As Sensing Material
SLO-2 Sensors, Signals, And Systems Light Polarization Microwave Motion Detectors Bio Chemical Sensors Plastics
S-2 SLO-1 Sensor Classification Light Scattering Microwave Motion Detectors Chemical Sensor Characteristics Metals, Ceramics
SLO-2 Units Of Measurements Geometrical Optics Ground Penetrating Radars Selectivity And Sensitivity Simple And Fraden Model Ceramics
S-3 SLO-1 Transfer Functions Radiometry Linear Optical Sensors Electrical And Electrochemical Sensors Steinhart And Hart Model Ceramics
SLO-2 Mathematical Models, Functional Approximations
Photometry Capacitive Occupancy Detectors Electrode Systems Structured Glass, Optical Glass
S-4 SLO-1
Linear Regression, Polynomial Approximations
Windows Triboelectric Detectors Potentiometric Sensors Nano Materials
SLO-2 Sensitivity, Piecewise Linear Approximation
Mirrors Coated And Prismatic Optoelectronic Motion Detectors - Structure
Conductometric Sensors Surface Processing, Spin Casting
S-5
SLO-1 Spline Interpolation, Lenses – Curved Surface Lenses Optoelectronic Motion Detectors - Distortion
Metal Oxide Semiconductor (MOS) Chemical Sensors
Vacuum Deposition
SLO-2 Multidimensional Transfer Functions Lenses – Fresnel Lenses Optoelectronic Motion Detectors - Efficiency
Elastomer Chemiresistors Sputtering
S-6 SLO-1 Calibration, Lenses – Flat Nano Lenses Optical Presence Sensors Chemicapacitive Sensors, Chem FET Chemical Vapor Deposition (CVD)
SLO-2 Computation Of Parameters Fiber Optics And Waveguides Pressure-Gradient Sensors Photoionization Detectors Electroplating
S-7 SLO-1 Computation Of A Stimulus Optical Efficiency Gesture Sensing (3-D Pointing) Physical Transducers, Acoustic Wave Devices
MEMS Technologies
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 47
SLO-2 Use Of A Analytical Equation Lensing Effect Gesture Sensing (3-D Pointing) Micro Cantilevers, Spectrometers Photolithography
S-8 SLO-1 Use Of Linear Piecewise Approximation Concentrators Tactile Sensors
Optical Transducers And Radiometric Selectivity
Silicon Micromachining
SLO-2 Iterative Computation Of Stimulus Coatings For Thermal Absorption Tactile Sensors Color Change Sensors Micromachining Of Bridges And Cantilevers
S-9
SLO-1 CASE STUDY: Sensors For Mobile Communication Devices - Requirements
Anti Reflective Coating CASE STUDY: Ionizing Radiation Detectors
Multi Sensor Arrays Lift Off, Wafer Bonding
SLO-2 CASE STUDY: Sensors For Mobile Communication Devices - Integration
CASE STUDY: Energy Harvesting CASE STUDY: Ionizing Radiation Detectors
Electronics Noses And Tongues LIGA In Wafer Bonding
Learning Resources
1. Phillip A. Laplante , “Handbook Of Modern Sensors – Physics Design And Applications” , 5th Edition, Springer Publication, 2015.
2. Xiaocong Fan, “Real-Time Embedded Systems,” 2nd Edition, Elsevier 2015.
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)#
Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
40 % - 30 % - 30 % - 30 % - 30% - Understand
Level 2 Apply
40 % - 40 % - 40 % - 40 % - 40% - Analyze
Level 3 Evaluate
20 % - 30 % - 30 % - 30 % - 30% - Create
Total 100 % 100 % 100 % 100 % 100 %
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers
Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Mr. Athif Shah, Chairman, Abe Semicondutor, [email protected] 1. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] 1. Dr. Soumya Ranjan Routray, SRMIST
2. Dr. Madan Kumar Lakshmanan, Senior Scientist, CEERI, [email protected] 2. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected] 2. Dr. Krishnaveni, SRMIST
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 48
Course Code
18ECE253T Course Name
UNSUPERVISED INTELLIGENCE IN CYBER PHYSICAL SYSTEM Course
Category E Professional Elective
L T P C
3 0 0 3
Pre-requisite Courses
18MAB101T Co-requisite
Courses NIL
Progressive Courses
NIL
Course Offering Department Electronics and Communication Data Book / Codes/Standards NIL
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Learning of unsupervised intelligence algorithms in cyber physical system 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
CLR-2 : Understand the working of model based reinforcement learning
Leve
l of T
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(Blo
om)
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ienc
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Sus
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abili
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Eth
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Indi
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Tea
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ork
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Pro
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CLR-3 : Learn with case study about reinforcement learning
CLR-4 : Use of python programming for reinforcement learning
CLR-5 : Unsupervised learning using SCIKIT learner, tensor flow and KERAS
CLR-6 : Gain overall understand of the cyber intelligent systems for real world applications
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Ability to understand reinforcement learning and its use for intelligence 1 80 70 H - - - - - - - - - - - - - -
CLO-2 : Able to design intelligent systems using cyber security standards 1 75 70 - M - - - - - - - - - - - -
CLO-3 : Implement different practical self learning systems with minimal supervision 3 75 70 - M H - - - - - - - - - - - H
CLO-4 : Develop deep reinforcement learning for designing cyber physical system 3 75 70 - H - - - - - - - - - - - H
CLO-5 : Come up with cost effective, reliable, robust and feasible designs for real world problems 1 70 70 - M - - - - - - - - - - - - -
CLO-6 : Design and implement real time systems and address the problems and limitations 2 70 70 - M - - - - - - - - - - M - -
DURATION (HOUR) REINFORCEMENT LEARNING AND CPS
MODEL BASED REINFORCEMENT LEARNING
DEEP REINFORCEMENT LEARNING & CASE STUDY
PYTHON PROGRAMMING FOR REINFORCEMENT LEARNING
UNSUPERVISED LEARNING USING SCIKIT-LEARNER, TENSORFLOW AND
KERAS
S-1 SLO-1 Overview Of Reinforcement Learning
Model Based Reinforcement Learning Introduction
Deep Reinforcement Learning Introduction Introduction To Reinforcement Learning Using Python
Unsupervised Learning Using Scikit-Learn
SLO-2 Comparison Of Different Reinforcement Learning Methods
Model Free Reinforcement Learning Deep Reinforcement Learning Examples Introduction To Reinforcement Learning Using Python
Dimensionality Reduction
S-2 SLO-1
Examples Of Different Reinforcement Learning Methods
Model Based Reinforcement Learning Principles,
Deep Reinforcement Learning Working Principles
Introduction To Reinforcement Learning Libraries Used
The Motivation For Dimensionality Reduction
SLO-2 Applications Of Different Reinforcement Learning Methods
Working &Applications Deep Reinforcement Learning Mathematical Modeling
Introduction To Reinforcement Learning Set Up Of Tools
Dimensionality Reduction Algorithms
S-3 SLO-1 History Of Reinforcement Learning Dynamic Programming
Deep Reinforcement Learning Value Function
Elements Of Reinforcement Learning Principal Component Analysis
SLO-2 History Of Reinforcement Learning Dynamic Programming Principles & Applications
Deep Reinforcement Learning Value Function Tools
Agent Environment Interface Singular Value Decomposition
S-4 SLO-1
Simulation Tool Kits For Reinforcement Learning
Partially Observable Markov Decision Process
Deep Reinforcement Learning Value Policy Tools
Types Of Reinforcement Environment Dictionary Learning
SLO-2 Simulation Tool Kit For Reinforcement Learning
Partially Observable Markov Decision Process - Architecture
Reinforcement Learning For Cyber Security Reinforcement Environment Platforms Independent Component Analysis
S-5
SLO-1 Overview Of Cyber Physical System Partially Observable Markov Decision Process – Working & Applications
Reinforcement Learning For Cyber Security – Examples
Reinforcement Environment Platform Call Function
Unsupervised Learning Using Tensor Flow
SLO-2 Examples Of Cyber Physical Systems Continuous Observable Markov Decision Process – Working & Applications
Reinforcement Learning For Cyber Security – Architectures
Getting Started With OPENAI And TENSORFLOW
Keras- Auto Encoders
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 49
S-6 SLO-1 Cyber Security-Introduction
Continuous Observable Markov Decision Process – Working & Applications
Reinforcement Learning For Cyber Security – Architectures
Setting Up Your Machine For OPEN AI And TENSOR FLOW
Auto Encoder: The Encoder And The Decoder
SLO-2 Cyber Security Examples Continuous Observable Markov Decision Process – Working & Applications
Reinforcement Learning For Cyber Security – System Function
OPENAI Gym, OPENAI Universe Under Complete Auto Encoders
S-7 SLO-1 Cyber Security Standards
Reinforcement Learning Predication Analysis
CASE STUDY: Online Cyber Attack Detection In Smart Grid –Introduction
TENSORFLOW Over Complete Auto Encoders
SLO-2 Reinforcement Learning Problems Reinforcement Learning Predication Analysis
CASE STUDY: Online Cyber Attack Detection In Smart Grid –Application
The Markov Chain And Markov Process Dense Vs. Sparse Autoencoders
S-8 SLO-1 Multi Armed Bandit Problem Reinforcement Learning Control Methods
CASE STUDY: Online Cyber Attack Detection In Smart Grid –System Design
Markov Decision Process Denoising Autoencoder
SLO-2 Contextual Bandit Problem Reinforcement Learning Advanced Algorithm
CASE STUDY: Online Cyber Attack Detection In Smart Grid –Working Principle
The Bellman Equation Variational Autoencoder
S-9
SLO-1 Contextual Bandit Problem Reinforcement Learning Advanced Algorithm Examples
CASE STUDY: Online Cyber Attack Detection In Smart Grid –System Model
Optimality, Solving The Bellman Equation
Hands-On With Autoencoder
SLO-2 Reinforce Learning Problem Reinforcement Learning Advanced Algorithm Applications
CASE STUDY: Online Cyber Attack Detection In Smart Grid –State Estimation
Optimality, Solving The Bellman Equation
Hands-On With Autoencoder
Learning Resources
1 Chong Li, Meikang Qiu, Reinforcement Learning for Cyber-Physical Systems and Cybersecurity Case Studies, 1st Edition, CRC Press.
2. Sudharsan Ravichandiran, Hands-On Reinforcement Learning with Python, 2nd Edition, Packet Publishing, 2018.
3. Ankur A. Patel, Hands-On Unsupervised Learning Using Python, 1st Edition, O'Reilly Media, Inc., March 2019
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)#
Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
40 % - 30 % - 30 % - 30 % - 30% - Understand
Level 2 Apply
40 % - 40 % - 40 % - 40 % - 40% - Analyze
Level 3 Evaluate
20 % - 30 % - 30 % - 30 % - 30% - Create
Total 100 % 100 % 100 % 100 % 100 %
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers
Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Mr. Athif Shah, Chairman, Abe Semicondutor, [email protected] 1. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] 1. Dr. P. Vijaya Kumar, SRMIST
2. Dr. Madan Kumar Lakshmanan, Senior Scientist, CEERI, [email protected] 2. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected]
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 50
Course Code
18ECE254T Course Name
REAL TIME CYBER PHYSICAL SYSTEM Course
Category E Professional Elective
L T P C
3 0 0 3
Pre-requisite Courses
18EES101J Co-requisite
Courses NIL
Progressive Courses
NIL
Course Offering Department Electronics and Communication Data Book / Codes/Standards NIL
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Practical knowledge on cyber physical machines 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
CLR-2 : Understanding of process, model and compositions of cyber physical systems
Leve
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CLR-3 : Identify the significance of networking and design components of cyber physical systems
CLR-4 : Create insights to the temporal logic and asynchronous model
CLR-5 : Analyze the working principle of continuous model and predictive model
CLR-6 : Utilize the concepts in cyber physical systems for the understanding of engineering and technology
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Use cyber physical system for engineering applications 1 60 65 - - - - - - H - - - - M - - -
CLO-2 : Design specific parts of the engineering schemes with cyber physical model 1 60 65 - - M - - - L - - - - - - - H
CLO-3 : Solve simple engineering problems with cyber physical solutions 2 65 65 - - H - - L M - - - - - - - -
CLO-4 : Apply the CPS model to replace older existing technology models 1 60 65 - - - - - - M - - - - - - - H
CLO-5 : Use Cyber physical systems for further new application and developments 1 60 65 - - M - - - - - - - - - - - H
CLO-6 : Apply the concepts of cyber physical systems in real time applications 2 60 65 - - - - L - - - - - - M - - H
Duration (hour)
INTRODUCTION TO REAL TIME SYSTEMS
SOFTWARE ARCHITECTURES FOR REAL-TIME SYSTEMS, REAL-TIME
SCHEDULING AND SHARING
CPS ARCHITECTURAL DESIGN, DATA MANAGEMENT AND ROUTING WITH WSN
TECHNOLOGIES
COMPUTING FUNDAMENTALS IN CYBER-
PHYSICAL SYSTEMS
REAL TIME CPS APPLICATIONS AND CASE STUDIES
S-1 SLO-1 Overview Of Embedded Systems Real-Time Tasks Wireless Sensor Networks Ubiquitous Computing History To Date
Cyber-Physical Systems Applications: Communication
SLO-2 Examples Of Embedded Systems Real-Time Tasks Distinguishing WSN, MANET, M2M, And CPS Ubiquitous Computing Fundamentals Consumer Interaction, Energy
S-2 SLO-1 Soft Real-Time Systems Round-Robin Architecture Cyber-Physical System Design Challenges Ubiquitous Computing Fundamentals Infrastructure, Health Care
SLO-2 Hard Real-Time Systems Round-Robin Architecture Cyber-Physical System Design Challenges Smart Devices: Components And Services
Manufacturing,
S-3 SLO-1 Spectrum Of Real-Time Systems Round Robin With Interrupts Cyber-Physical Systems Architecture Tagging, Sensing, And Controlling Military
SLO-2 Examples Of Real Time Systems Queue-Based Architecture Cyber-Physical Systems Architecture Autonomous Systems In Ubiquitous Computing
Robotics, Transportation
S-4 SLO-1 Case Study: Real Time Systems
Real-Time Scheduling: Clock-Driven Approach
The Role Of Wsn Technologies In Cpss Autonomous Systems In Ubiquitous Computing
Smart Cities And The Internet Of Everything
SLO-2 Introduction To Cross-Platform Development
Real-Time Scheduling: Clock-Driven Approach
The Role Of WSN Technologies In Cpss Case Study: Robot Manipulator Medical Cyber-Physical Systems: Introduction
S-5
SLO-1 Hardware Architecture Real-Time Scheduling: Rate-Monotonic Approach
Towards A New Cps Architecture Introduction To Systems Engineering Background And Related Works
SLO-2 Software Development: Software Design Real-Time Scheduling: Rate-Monotonic Approach
Data Management: Wsn Vs. Wsn-Cps Introduction To Systems Engineering Technical Components
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 51
S-6 SLO-1 System Programming Language C/C++ Real-Time Scheduling: Sporadic Server Data Management Activities Introduction To Software Engineering
Towards Cognitive Prostheses, Challenges And Opportunities
SLO-2 System Programming Language C/C++ Real-Time Scheduling: Sporadic Server Data Management Activities Introduction To Software Engineering Mobile Wsn-Cps Applications
S-7 SLO-1 Build Target Images Resource Sharing: Shared Variables
Cyber-Physical Cloud Computing: Opportunities And Challenges
V-Model Smart Space Systems
SLO-2 Build Target Images Shared Memory Cyber-Physical Cloud Computing: Opportunities And Challenges
Agile Software Development Methodology
Emergency Response Systems
S-8 SLO-1 CASE STUDY: Building A QNX Image Semaphore
Design Challenges And Issues For Routing In WSN Within The Context Of CPS
Comparison Of The V-Model And The Agile Software Development Methodology
Human Activity Inference
SLO-2 Transfer Executable File Object To Target Semaphore Routing Protocols In Wsns For Cpss Requirements In Software Design In Cyber-Physical Systems
Smart Factory
S-9 SLO-1 Integrated Testing On Target Mutex
Future Directions Of Routing Protocols In WSN For CPS
Requirements In Software Design In Cyber-Physical Systems
CASE STUDY: Cyber-Physical Vehicle Tracking System
SLO-2 System Production Condition Variable Case Study: Wsn-Cps Applications Maritime Area Case Studies Case Study: Cyber-Physical Vehicle Tracking System
Learning Resources
1. Kuodi Jain-Real Time Sysytems , 1st edition, Intech Open Publshing, 2015. 2. Xiaocong Fan- Real-Time Embedded Systems Design Principles and Engineering Practices,
1st Edition, Newnes Publications, 2016
3. Sherali Zeadally and Nafaaˆ Jabeur- Cyber-Physical System Design with Sensor Networking Technologies, 1st Edition, IEEE Design & Test, 2017.
4. Dietmar P.F. Moller- Guide to Computing Fundamentals in Cyber-Physical Systems, 2nd edition, Springer Publications, 2016.
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)#
Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
40 % - 30 % - 30 % - 30 % - 30% - Understand
Level 2 Apply
40 % - 40 % - 40 % - 40 % - 40% - Analyze
Level 3 Evaluate
20 % - 30 % - 30 % - 30 % - 30% - Create
Total 100 % 100 % 100 % 100 % 100 %
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers
Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Mr. Athif Shah, Chairman, Abe Semicondutor, [email protected] 1. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] 1. Dr Phani Kumar, SRMIST
2. Dr. Madan Kumar Lakshmanan, Senior Scientist, CEERI, [email protected] 2. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected]
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 52
Course Code
18ECE350T Course Name
CYBER PHYSICAL INTERFACE AND AUTOMATION Course
Category E Professional Elective
L T P C
3 0 0 3
Pre-requisite Courses
18ECE251T Co-requisite
Courses NIL
Progressive Courses
NIL
Course Offering Department ECE Data Book / Codes/Standards NIL
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Study the cyber physical systems built-on Wireless sensor networks 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
CLR-2 : Learn the synthesis for cyber physical systems
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CLR-3 : Gain knowledge on security features of cyber physical systems
CLR-4 : Analyse the real-time scheduling for cyber physical systems
CLR-5 : Enhance the scientific computing skills on medical cyber physical systems
CLR-6 : Develop Cyber physical systems for interfacing and automation
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Appreciate the features of localization of wireless sensor networks using CPS 3 80 70 L H - H L - - - L L - H - - -
CLO-2 : Synthesize the feedback control systems for CPS 3 85 75 M H L M L - - - M L - H - - -
CLO-3 : Analyse security issues in CPS 3 75 70 M H M H L - - - M L - H - - -
CLO-4 : Design the real time scheduling algorithms for CPS 3 85 80 M H M H L - - - M L - H - - -
CLO-5 : Apply the automated concepts in medical CPS. 3 85 75 H H M H L - - - M L - H - - -
CLO-6 : Implement basic applications with automation 3 80 70 L H - H L - - - L L - H - - -
Duration (hour) CYBER-PHYSICAL SYSTEMS BUILT ON
WIRELESS SENSOR NETWORKS SYNTHESIS FOR
CYBER-PHYSICAL SYSTEMS SECURITY OF CYBER-PHYSICAL
SYSTEMS REAL-TIME SCHEDULING FOR CYBER-
PHYSICAL SYSTEMS MEDICAL CYBER-PHYSICAL SYSTEMS
S-1 SLO-1 Introduction And Motivation
Introduction Introduction Introduction Introduction
SLO-2 Medium Access Control Virtual Medical Devices
S-2 SLO-1
System Description And Operational Scenarios
Basic Techniques Basic Techniques Basic Techniques System Description And Operational Scenarios
SLO-2 Routing Preliminaries Discrete Verification Scheduling With Fixed Timing Parameters Clinical Scenarios
S-3 SLO-1 Node Localization Problem Definition Cyber Security Requirements Memory Effects Key Design Drivers And Quality Attributes
SLO-2 Clock Synchronization Trends
S-4 SLO-1
Power Management Solving The Synthesis Problem
Attack Model Advanced Techniques
Quality Attributes And Challenges Of The MCPS Domain
SLO-2 Construction Of Symbolic Models Smart Alarms And Clinical Decision Support Systems Trends
S-5 SLO-1 Key Design Drivers And Quality Attributes Controller Timing
Countermeasures Multiprocessor/Multicore Scheduling High-Confidence Development Of MCPS
SLO-2 Physically Aware Control Design For Resource Efficiency Closed-Loop System
S-6 SLO-1 Real-Time Aware Advanced Techniques Advanced Techniques
Accommodating Variability And Uncertainty
On-Demand Medical Devices And Assured Safety
SLO-2 Runtime Validation Aware Construction Of Symbolic Models Real-Time Verification Assurance Cases
S-7 SLO-1 Security Aware Continuous-Time Controllers Hybrid Verification Managing Other Resources Practitioners’ Implications
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 53
SLO-2 Software Tools MCPS Developer Perspective
S-8 SLO-1
Practitioners’ Implications Reducing The Computation Time
System Theoretic Approaches Rhythmic Tasks Scheduling MCPS Administrator Perspective
SLO-2 Analysis And Simulation Of Feedback Control Systems
MCPS User Perspective
S-9 SLO-1
Summary And Open Challenges Summary And Open Challenges Summary And Open Challenges Summary And Open Challenges Summary And Open Challenges SLO-2
Learning Resources
1. Rajeev Alur, Principles of Cyber Physical Systems, 1st Edition, MIT Press 2015. 2. Raj Rajkumar , “Cyber Physical Systems,” 2nd Edition, Elsevier 2015 3. Edward D Lamie, “Computing Fundamentals Of Cyber Physical Systems ” , 2nd Edition, Newnes Elsevier
Publication.
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)#
Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
40 % - 30 % - 30 % - 30 % - 30% - Understand
Level 2 Apply
40 % - 40 % - 40 % - 40 % - 40% - Analyze
Level 3 Evaluate
20 % - 30 % - 30 % - 30 % - 30% - Create
Total 100 % 100 % 100 % 100 % 100 %
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers
Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Mr. Athif Shah, Chairman, Abe Semicondutor, [email protected] 1. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] 1. Dr. Sangeetha M, SRMIST
2. Dr. Madan Kumar Lakshmanan, Senior Scientist, CEERI, [email protected] 2. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected]
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 54
Course Code
18ECE351T Course Name
HIGH PERFORMANCE COMPUTING FOR CYBER PHYSICAL SYSTEM Course
Category E Professional Elective
L T P C
3 0 0 3
Pre-requisite Courses
18ECE250T Co-requisite
Courses NIL
Progressive Courses
NIL
Course Offering Department Electronics and Communication Data Book / Codes/Standards NIL
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Understanding the role of supercomputers 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
CLR-2 : Implementing the HPC Applications on Grid and cloud Infrastructures
Leve
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oder
n T
ool U
sage
Soc
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& C
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S
usta
inab
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E
thic
s
Indi
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Tea
m W
ork
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Pro
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O –
3
CLR-3 : JGRIM Simplifies the process of porting applications
CLR-4 : Learning on Scheduled Algorithm
CLR-5 : Real – world Infrastructures-Research area
CLR-6 : Big Data challenge and Applications in cloud environment customization design
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Improve products reduce the time taken for develop new products-HPC 1 90 75 H - - - - - - - - - - - - - -
CLO-2 : Reduce the production cost 1 80 70 H - - - - - - - - - - - - - -
CLO-3 : High performance computing systems can be highly useful to analyze the data 2,3 90 75 - M H - H - - - - - - - - - -
CLO-4 : Big data as our ability to gather the information 2,3 90 75 - M H - H - - - - - - - - - -
CLO-5 : Ability to learn the Algorithm 2 80 75 - M H - L - - - - - - - - - -
CLO-6 : HPC main advantage learning here( Processing speed super computer) 2 90 75 - M H - H - - - H - - - M - L
Duration (hour)
INTRODUCTION TO SUPER COMPUTERS
SCHEDULING ARCHITECTURES PRIVACY & SECURITY FRAMEWORK DATA EXECUTION MODELS EMERGING
APPLICATIONS
S-1
SLO-1 Introduction Of Super Computers And Grids
Introduction To Scheduling- Moldable Job Allocation For Handling Resource Fragmentation In Computational Grid
Introduction To Security Big Data Architectures Introduction To Emerging Big Data Application
SLO-2 Grids And Supercomputers, Grids Do Support Supercomputing
Computational Grid Model And Experimental Setting
A Policy Based Security Framework For Privacy-Enhancing Data Access And Usage Control In Grids
Dataflow Model For Cloud Computing Frameworks In Big Data
Matrix Factorization For Drug Target Interaction Prediction
S-2 SLO-1 Grids Cannot Replace Supercomputers
Moldable Job Allocation On Homogeneous Parallel Computer ,Moldable Job Allocation In Heterogeneous Grid
Privacy Management In Large Scale Distributed Systems, Managing Initial Data Access,
Introduction Classification Based Methods
SLO-2 The Role Of Supercomputers In Grids Comparison With Multi-Site Co-Allocation And Conclusion
Controlling Data Usage, Grids And Their Requirements For Privacy Management
Cloud Computing Frameworks Neighborhood Regularization Logistic Matrix-Problem Formalization
S-3
SLO-1 A Public-Private Supercomputing Grid Partnership Prerequisites And Problems
Introduction To Speculative Scheduling Of Parameter Sweep Applications Using Job Behavior Descriptions
Architecture Of A Policy Based Security Framework For Privacy-Enhancing Data Access And Usage Control In Grids, Application Of The Security Framework To A Xacml-Based Privacy Management Architecture
Batch, Iterative, Incremental Processing Frameworks
Logistic Matrix Factorization, Neighborhood Regularization
SLO-2 Mode Of Operation Architecture Overview Integration Of The Security Framework’s Privacy Management Components On The Service Provider Side, Summery
Streaming Processing Frameworks, General Dataflow Frameworks
Combined Model,Neighbourhood Smoothing
S-4 SLO-1 The Public-Private Grid, Discussion Of Results, Conclusion
Job Behavior Description, Simple Description
Adaptive Control Of Redundant Task Execution For Dependable Volunteer Computing-Instruction
Application Examples Experimental Settings, Comparison, Benefits
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 55
SLO-2 Introduction To Porting Hpc Applications To Grids And Clouds -Applications And The Grid Infrastructure
Complex Description Related Work, Statistical Resource Availability Characterizing, Root Cause Analysis Of Failures
Controllable Data Execution Model Parameter Sensitive Analysis
S 5-6
SLO-1
Applications And Resource Management Generating Simple Job Descriptions, Generating Complex Job Descriptions
Fitting Distribution to Empirical Availability Data, Availability Prediction, A Heuristics-Based Failure Probability Estimation, Life Cycle Of A Volunteer Peer
Design Of A Processor Core Customized For Stencil Computation-Introduction
Predicting Novel Interactions SLO-2
S-7
SLO-1 Applications And Data Management Complex Descriptions With Mutation, Scheduling Strategies
Failure Probability Estimation, Least Failure Probability Dispatch Policy
Related Work-Customizable Design And Processors, Micro Architecture, Stencil Computation
Overview Of Neural Network Accelerators
SLO-2 The Simple API For Grid Applications (Saga)
Static Data Feeder Strategy, Dynamic Data Feeder Strategy
An Enhanced Workflow Management Mechanism, The Task Selection
Customization Design, Flow, Array Padding And Loop Tiling, BW Optimizations.
Architectures Of Hardware Accelerators –ASIC, GPU
S-8 SLO-1
Grid Applications And Data, Shared Data Access
Implementation, Scheduler Evaluation Results, Baseline Policies SIMD, DMA Stencil Computation and others
FPGA, Modern Storage Accelerator
SLO-2 Data Topology, Data Volume Description Generator, Description Repository Service
Time Dependent Schrödinger’s Wave Equation, Performance Evaluation
Implementation Parallel Programming Models
S-9
SLO-1 Porting And Programming Grid Applications
Simulation Results Comparison With The Simple Redundant Task Dispatch Policy, Comparison With The Greedy Dispatch
Test Results Middleware Of Neural Networks
SLO-2 Grid Programming Models And Environments
Summary And Conclusion Effects Of Window Size On The Process Time, Improvement Of The Performance By Identifying Worker Types
Introduction To Electro Migration Alleviation Techniques
Latest Developments
Learning Resources
1. Emmanuel Udoh, Cloud ,grid and High performance computing Emerging Applications, 1st Edition, IGI Global, 2011.
2. Chao Wang, High performance computing for Big Data Methodologies and Applications, 1st Edition, Chapman & Hall Press Publications, 2020.
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)#
Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
40 % - 30 % - 30 % - 30 % - 30% - Understand
Level 2 Apply
40 % - 40 % - 40 % - 40 % - 40% - Analyze
Level 3 Evaluate
20 % - 30 % - 30 % - 30 % - 30% - Create
Total 100 % 100 % 100 % 100 % 100 %
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers
Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Mr. Athif Shah, Chairman, Abe Semicondutor, [email protected] 1. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] 1. Dr. C.T.Manimegalai, SRMIST
2. Dr. Madan Kumar Lakshmanan, Senior Scientist, CEERI, [email protected] 2. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected]
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 56
Course Code
18ECE352T Course Name
CYBER PHYSICAL CONTROL SYSTEM Course
Category E Professional Elective
L T P C
3 0 0 3
Pre-requisite Courses
18ECS201T, 18ECE252T Co-requisite
Courses NIL
Progressive Courses
NIL
Course Offering Department Electronics and Communication Data Book / Codes/Standards NIL
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Understand the basics and advanced concepts of control systems 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
CLR-2 : Gain the knowledge of industrial controllers process and their instrumentation
Leve
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(Blo
om)
Exp
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d P
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)
Exp
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)
Eng
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Kno
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& D
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& C
ultu
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Env
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Sus
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Eth
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Indi
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Tea
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Com
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Pro
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1
PS
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2
PS
O –
3
CLR-3 : Comprehend basic symbology and process control elements and techniques
CLR-4 : be acquainted with Industrial standards and methods for calibration and controller tuning
CLR-5 : Acquire knowledge on Control systems networking and cyber connections
CLR-6 : Grasp significant knowledge on industrial control systems and networking standards
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Understand mathematical (state) equations of complex control systems and their stability 2 60 60 H M - - - - - - - - - - - - -
CLO-2 : Design optimal control process for industrial instrumentation 2 60 60 - M H - - - - - - - - - - - -
CLO-3 : Understand process control instrumentation and design various control flow diagrams 1 60 60 - M H - - - - - - - - - - - -
CLO-4 : Maintain Industrial standards and methods for calibration of industrial instrumentation 1 60 60 - M H - - - - - - - - - - - -
CLO-5 : Design PLC, SCADA, HART protocols and wireless interfacings 2 60 60 - M H - - - - - - - - - M - H
CLO-6 : Improve the standards of industrial instrumentation and networking protocols 2 60 60 - M H - M - - - M - - - H L -
Duration (hour)
CONTROL SYSTEMS BASICS AND BEYOND
INDUSTRIAL PROCESS TECHNIQUES AND INSTRUMENTATION
PROCESS-CONTROL METHODS INDUSTRIAL STANDARDS AND
METHODS FOR CALIBRATION AND CONTROLLER TUNING
CYBER SYSTEMS AND NETWORKING
S-1 SLO-1
Elements of Open- and Closed-Loop Systems
Need of Controllers Batch Processes Instrument Calibration and Controller Tuning
Programmable Logic Controller Basics
SLO-2 Transfer function Open-Loop Control Batch Processes Control Requirements Reasons for Performing Calibrations Requirement of communication networks for PLC, PLC to Computer.
S-2
SLO-1 Continuous-time systems, and convolution Closed-Loop Control Types of Batch Processes Calibration Preparation Elements of SCADA system
SLO-2 Impulse response and step response Process Behavior Continuous Processes Standard Calibration Procedure Discrete control, Analog control, Master Terminal Unit, Remote Terminal Unit, Operator interface
S-3 SLO-1 Feedback Control Systems Selecting a Controller
Continuous Processes Control Requirements
Five-Point Calibration Procedure Distributed Control System (DCS)
SLO-2 Basic Characteristics of feedback control systems
On-Off Control Measurement Devices (Sensors): Dynamic, Static
Process Calibrators DCS Architectures, Local Control Unit
S-4 SLO-1 Stability, reference tracking Continuous Control, Proportional Mode Feedback Loop Interface Instruments Sensor Calibration
HART communication protocol, communication modes
SLO-2 Disturbance rejection, sensitivity and robustness
Integral Mode, Derivative Mode Block diagram of a closed-loop automated system
Transmitter Calibration Industrial Wireless Technologies
S-5
SLO-1 Typical control system structures for SISO, MISO, SIMO, and MIMO plants
Advanced Control Techniques Transmitters, Transducers Tuning the Controller Wireless Architecture, Topologies
SLO-2 State-space design Cascade Control Monitoring Instruments: Indicators, Alarms, Recorders
Trial-and-Error Tuning Method Wireless Infrastructure in Industrial Control Systems,
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 57
S-6 SLO-1 State variables Feed-Forward Control
Manipulation Devices (The Final Control Element): The Solenoid Valve, DC and AC Motors, The Control Valve
Ziegler-Nichols Tuning Methods Self-Organizing Networks
SLO-2 Solution of state equations Ratio Control Instrumentation Symbology Ziegler-Nichols Continuous-Cycling Method
Wireless Standards
S-7 SLO-1 Eigenvalues and eigenvectors Adaptive Control General Instrument Symbols
Ziegler-Nichols Continuous-Cycling Method
Threats in Industrial Control Systems
SLO-2 Jacobian linearization technique Pneumatic Controllers Tag Numbers Ziegler-Nichols Reaction-Curve Tuning Method
Network Backbones: Hubs, Switches, Bridges, Gateways.
S-8 SLO-1 State transformations and diagonalisation Panel-Mounted Controllers Line Symbols
Ziegler-Nichols Reaction-Curve Tuning Method
Hierarchy of Industrial Networks
SLO-2 Transformation to phase-variable canonical form
Personal Computers Valve and Actuator Symbols Controller Autotuning Troubleshooting I/O Interfaces
S-9
SLO-1 Basics of Controllability and Observability Programmable Logic Controllers Reading a Single Loop PID controller Network Communication Standards
SLO-2 Duality property. Stability Distributed Control Systems (DCS) Information Block PID controller tuning rules
Fieldbus Networks
Learning Resources
1. Nagrath I.J and Gopal M, “Control Systems Engineering”, New Age Publishers, 5 th Edition, 2009. 2. Cyber-security of SCADA and Other Industrial Control Systems, Editors: Colbert, Edward J.
M., Kott, Alexander (Eds.) ISBN 978-3-319-32125-7 3. Frank Petruzella. D, “Programmable Logic Controllers”, Tata McGraw Hill Third Edition, 2010.
4. Bolton. W, “Progra ble Logic Controllers mma ” Fifth Edition, Elsevier Newnes, 2009. 5. Michael Lucas, “Distributed Control Systems”, Van Nostrand Reinhold Co., 1986. 6. Industrial Automated Systems: Instrumentation and Motion Control, Terry Bartelt, ISBN-13: 978-1-4354-
8888-5
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)#
Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
40 % - 30 % - 30 % - 30 % - 30% - Understand
Level 2 Apply
40 % - 40 % - 40 % - 40 % - 40% - Analyze
Level 3 Evaluate
20 % - 30 % - 30 % - 30 % - 30% - Create
Total 100 % 100 % 100 % 100 % 100 %
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers
Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Mr. Athif Shah, Chairman, Abe Semicondutor, [email protected] 1. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] 1. Dr. Bandaru Ramakrishna, SRMIST
2. Dr. Madan Kumar Lakshmanan, Senior Scientist, CEERI, [email protected] 2. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected] 2. Dr. Vivek Maik, SRMIST
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 58
Course Code
18ECE353T Course Name
CYBER SECURITY Course
Category E Professional Elective
L T P C
3 0 0 3
Pre-requisite Courses
18ECE250T Co-requisite
Courses NIL Progressive
Courses NIL
Course Offering Department Electronics and Communication Data Book / Codes/Standards NIL
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Learn Cyber Security Concepts 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
CLR-2 : Understand the standards and protocols for cyber security
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& C
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Env
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Sus
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Eth
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Indi
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Tea
m W
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Pro
ject
Mgt
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Life
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1
PS
O -
2
PS
O –
3
CLR-3 : Design and understand cryptography and secure communications
CLR-4 : Understand security and privacy threats in computer networks
CLR-5 : Develop Deep Understanding On cyber crime issues and forensics
CLR-6 : Gain Overall Understand Of The cyber security for real world applications
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Ability to understand cyber security working and protocols 1 60 70 - H - - L - - - - - - - - -
CLO-2 : Able to design secure systems using cyber security standards 2 60 70 M - - - - - - - - - M - - -
CLO-3 : Implement different practical digital encrypted systems with minimal supervision 3 60 70 - M H - H - - - - - - - - L
CLO-4 : Develop Deep Understanding on selection of hardware and software’s for designing cyber physical system 1 60 70 - M - - - - - - - - H - - -
CLO-5 : Come up with cost effective, reliable, robust and feasible designs for real world problems 3 60 70 - M M - H - - - - H - - - H
CLO-6 : Design and implement real time systems and address the problems and limitations 3 60 70 - - M - H - - - - - H L - M
DURATION (HOUR)
DIGITAL SECURITIES ONLINE ANONYMITY CRYPTOGRAPHY AND
SECURE COMMUNICATION CYBER CRIME ISSUES AND
INVESTIGATION DIGITAL FORENSICS
S-1 SLO-1 Introduction Introduction Introduction To Cryptography Unauthorized Access Introduction To Digital Forensics,
SLO-2 Types Of Cyber Attacks Anonymous Networks Difference Between Encryption & Cryptography
Computer Intrusions, Forensic Software And Hardware
S-2 SLO-1 Digital Privacy TOR Networks Cryptographic Functions White Collar Crimes, Analysis And Advanced Tools,
SLO-2 Online Tracking TOR Applications Cryptographic Types Viruses And Malicious Code, Forensic Technology And Practices
S-3 SLO-1 Privacy Laws I2P Network Cryptographic Applications Internet Hacking And Cracking, Forensic Ballistics And Photography
SLO-2 Malware - Definition And Working Principle I2P Configurations Cryptographic Systems Trust Models Virus Attacks, Face, Iris And Fingerprint Recognition
S-4 SLO-1 Hacking - Definition And Working Principle Freenet Principle & Working Cryptographic Key Pair Software Piracy, Intellectual Property Audio Video Analysis,
SLO-2 Pharming - Definition And Working Principle
Darknet Principle & Working Disk Encryption Using Windows Bitlocker
Mail Bombs, Exploitation Windows System Forensics
S-5
SLO-1 Phishing - Definition And Working Principle Sharenet Principle & Working Disk Encryption Using Open Source Tools
Digital Laws And Legislation, Law Enforcement Roles And Responses,
Linux System Forensics,
SLO-2 Ransomware- Definition And Working Principle
Anonymous OS – Tails Multi Task Encryption Tools Investigation Tools, E-Discovery
Comparison Between Windows & Linux System Forensics
S-6 SLO-1 Antivirus - Definition And Working Principle Secure File Sharing Attacking Cryptographic Systems EDRM Model, Digital Evidence Collection WIFI Security (War-Driving)
SLO-2 Other Security Solution VPN Design And Architecture Countermeasures Against Cryptography Attacks
Evidence Preservation, E-Mail Investigation
Network Forensics,
S-7 SLO-1 Secure Online Browsing Proxy Server Securing Data In Transit E-Mail Tracking, Ip Tracking Network Forensics - Application & Examples
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 59
SLO-2 Email Security Connection Leak Testing Cloud Storage Encryption E-Mail Recovery, Mobile Forensics
S-8 SLO-1 Social Engineering Secure Search Engine Encrypt DNS Traffic Search And Seizure Of Computers,
Mobile Forensics – Application & Examples
SLO-2 Secure WIFI Settings Web Browser Privacy Configuration Encrypt DNS Traffic For Email Communication
Recovering Deleted Evidences Cloud Forensics.
S-9
SLO-1 Cloud Storage Security Anonymous Payment Attacking Cryptographic Systems Password Cracking Cloud Forensics Application & Examples
SLO-2 IOT Security Payment Security Measures Securing Data In Transit Recovering Hard Disk Data Net Neutrality & Challenges Of Forensic Science
Learning Resources
1. Digital Privacy and Security Using Windows: A Practical Guide By Nihad Hassan, Rami Hijazi, 1st Edition, Apress Publications, 2017
2. Digital Forensics, DSCI - Nasscom, 2012. 3. Cyber Crime Investigation, DSCI - Nasscom, 2013.
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)#
Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
40 % - 30 % - 30 % - 30 % - 30% - Understand
Level 2 Apply
40 % - 40 % - 40 % - 40 % - 40% - Analyze
Level 3 Evaluate
20 % - 30 % - 30 % - 30 % - 30% - Create
Total 100 % 100 % 100 % 100 % 100 %
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers
Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Mr. Athif Shah, Chairman, Abe Semicondutor, [email protected] 1. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] 1. Dr. Vivek Maik, SRMIST
2. Dr. Madan Kumar Lakshmanan, Senior Scientist, CEERI, [email protected] 2. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected]
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 60
Course Code
18ECE354T Course Name
CLOUD AND DISTRIBUTED SYSTEMS FOR CYBER PHYSICAL SYSTEM Course
Category E Professional Elective
L T P C
3 0 0 3
Pre-requisite Courses
18ECE254T Co-requisite
Courses NIL
Progressive Courses
NIL
Course Offering Department Electronics and Communication Data Book / Codes/Standards NIL
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Understand the fundamental ideas behind cloud computing, the evolution of the paradigm, its applicability; Benefits, as well as current and future challenges.
1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
CLR-2 : Learn cloud enabling technologies, virtualization concepts and virtual machines.
Leve
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(Blo
om)
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Ana
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& D
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Too
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Soc
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& C
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Sus
tain
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Eth
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Indi
vidu
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Tea
m W
ork
Com
mun
icat
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Pro
ject
Mgt
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Life
Lon
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PS
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1
PS
O -
2
PS
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CLR-3 : Explore distributed system models and computer clusters for scalable parallel computing.
CLR-4 : Understand the concept of intelligent data in cloud and distributed computing.
CLR-5 : Explore distributed cloud storage technologies and relevant distributed file systems.
CLR-6 : Gain overall knowledge of cloud and distributed computing in real world applications.
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Explain the fundamental ideas behind cloud computing, cloud models and current trends. 1,2 80 80 H H - - - - - - - - - - H - -
CLO-2 : Analyze the need for virtualization in a cloud environment and outline their role in enabling the cloud computing system Model.
1,2 85 80 H H - - - - - - - - - - H - -
CLO-3 : Apply distributed system model and understand the design principles of computer clusters. 2,3 90 85 H H - - - - - - - - - - H - -
CLO-4 : Know the use of computational methods associated with cloud and distributed computing. 2,3 90 85 H H - - - - - - - - - - H - -
CLO-5 : Illustrate the fundamental concepts of distributed algorithms, standards and protocols. 1,2,3 80 80 H H - - - - - - - - - - H - -
CLO-6 : Understand the state of the art trend in the cloud and distributed computing. 1,2,3 85 85 H H - - - - - - - - - - H - -
Duration
(Hour) CLOUD COMPUTING CLOUD TECHNOLOGY DATA & INTELLIGENCE IN THE CLOUD DISTRIBUTED COMPUTATIONS
DISTRIBUTED ALGORITHMS
S-1 SLO-1 What Is Cloud Computing Introduction
Historic Review Of Database Storage Model
Distributed Computing Definition Topology Abstraction And Overlays
SLO-2 Cloud Computing Service Models Web Technology – HTTP, HTML Relational Is The New Hoover Relation To Computer System Concepts Classification Of Algorithms And Basic Concepts
S-2 SLO-1 Cloud Computing Deployment Models Web Technology – XML, JSON
Database As A Service, Data Storage In The Cloud
Relation To Parallel Multiprocessor / Multicomputer Systems
Complexity Measure And Concepts
SLO-2 Public Cloud – Definitions, Advantages Web Technology – Javascript , AJAX Backup Or Disaster Recovery Message Passing Systems Versus Shared Memory Systems
Program Structure
S-3 SLO-1 Private Cloud – Definitions, Advantages Model View Controller
Business Drivers For The Adoption Of Different Data Models
Primitives For Distributed Computations Elementary Graph Algorithms
SLO-2 Hybrid Cloud – Definitions, Advantages Automatic Computing Basically Available, Soft State, Eventually Consistent (BASE)
Synchronous Vs Asynchronous Executions Synchronizers
S-4 SLO-1
Community Cloud – Definitions, Advantages
Virtualization – Application Virtualization Column Oriented, Document Oriented And Key Value Stores
Design Issues And Challenges Maximal Independent Set (MIS)
SLO-2 Internal And External Factors For Choosing Cloud Model
Desktop Virtualization, Server Virtualization
Intelligence In The Cloud, Web 2.0 Selection And Coverage Of Topics Connected Dominating Set
S-5 SLO-1 Legal Aspects Of Cloud Computing Server Virtualization, Storage Virtualization Relational Databases
A Distributed Program And Model Of Distributed Executions
Compact Routing Tables
SLO-2 Privacy And Security In Cloud Implementing Virtualization Text Data, Natural Language Processing Models Of Communication Networks Leader Election
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 61
S-6 SLO-1 The Ethical Dimension In Cloud Hypervisor
Intelligent Searching, Search Engine Overview,
Global State Of The Distributed Systems Challenges In Designing Distributed Graph Algorithms
SLO-2 Social Aspects In The Cloud Map Reduce The Crawler, The Indexer, Ranking, Vector Space Model
Cuts Of The Distributed Computation Object Replication Problems
S-7 SLO-1 Economic And Political Aspects Map Reduce Example
Classification, Measuring Retrieval Performance
Past And Future Cones Of An Event Message Ordering Paradigms
SLO-2 Green Information Technology Scaling With Map Reduce Clustering, Web Structure Mining Models Of Process Communications Asynchronous Execution With Synchronous Communication
S-8 SLO-1 Cloud Economics
Server Failure, Programming Model Of Map Reduce
Enterprise Search, Multimedia Search, Collective Intelligence
Framework For A System Of Logical Time With Clocks
Synchronous Program Order On A Synchronous System
SLO-2 Outsourced , Managed And Services In The Cloud
Apache Hadoop Tagging, Recommendation And Collective Intelligence In The Enterprise
Scalar Time, Vector Time And Efficient Implementation Of Vector Clocks
Group Communication And Causal Order
S-9 SLO-1 Total Cost Of Ownership A Brief History Of Hadoop Personalization, Crowd Sourcing Jard-Jourdans Adaptive Technique Total Order And Multicast
SLO-2 Categories Of Cost Efficiencies Amazon Elastic Map Reduce Text Visualization Matrix And Virtual Time Propagation Trees For Multicast
Learning Resources
1. Richard Hill, Laurie Hirsch, Peter Lake, And Siavash Moshiri, Guide To Cloud Computing And Practice, 2nd Edition, Springer Verlag, 2013.
2. Ajay D Kshemkalyani And Mukesh Singhal, “Distributed Computing – Principles, Algorithms And Systems,” 2nd Edition, Cambridge University Press, 2008.
3. Dan C. Marinescu,” Cloud Computing Theory And Practice”, 2nd Edition, Elsevier Press, 2018.
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)#
Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
40 % - 30 % - 30 % - 30 % - 30% - Understand
Level 2 Apply
40 % - 40 % - 40 % - 40 % - 40% - Analyze
Level 3 Evaluate
20 % - 30 % - 30 % - 30 % - 30% - Create
Total 100 % 100 % 100 % 100 % 100 %
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers
Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Mr. Athif Shah, Chairman, Abe Semicondutor, [email protected] 1. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] 1. Dr. Vasanthi S,SRMIST
2. Dr. Madan Kumar Lakshmanan, Senior Scientist, CEERI, [email protected] 2. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected] 2. Dr. Vivek Maik, SRMIST
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 62
Course Code
18ECE355T Course Name
DESIGN OF CYBER PHYSICAL SYSTEM Course
Category E Professional Elective
L T P C
3 0 0 3
Pre-requisite Courses
18ECE253T Co-requisite
Courses NIL
Progressive Courses
NIL
Course Offering Department Electronics and Communication Data Book / Codes/Standards NIL
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Able to understand the design of human in the loop cyber physical systems 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
CLR-2 : Design knowledge of energy cyber physical systems
Leve
l of T
hink
ing
(Blo
om)
Exp
ecte
d P
rofic
ienc
y (%
)
Exp
ecte
d A
ttain
men
t (%
)
Eng
inee
ring
Kno
wle
dge
Pro
blem
Ana
lysi
s
Des
ign
& D
evel
opm
ent
Ana
lysi
s, D
esig
n, R
esea
rch
Mod
ern
Too
l Usa
ge
Soc
iety
& C
ultu
re
Env
ironm
ent &
Sus
tain
abili
ty
Eth
ics
Indi
vidu
al &
Tea
m W
ork
Com
mun
icat
ion
Pro
ject
Mgt
. & F
inan
ce
Life
Lon
g Le
arni
ng
PS
O -
1
PS
O -
2
PS
O –
3
CLR-3 : Learn how Symbolic synthesis for cyber physical systems works
CLR-4 : Design principles of Intelligent wireless sensor networks in cyber physical systems
CLR-5 : Through simple hands on exercise learn and implement humans in the loop software
CLR-6 : Learn overall procedural and functional steps involved in design of cyber physical systems
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Able to design the cyber physical systems with Industry 4.0 standards 2,3 70 70 L M H - - - - - - - - - - - -
CLO-2 : Able to design wireless sensor systems using intelligent methods 2,3 70 70 L M H - - - - - - - - - - - -
CLO-3 : Implement different practical cyber physical systems with minimal supervision 2,3 70 70 L M H - - - - - - - - - - - -
CLO-4 : Develop Deep Understanding on selection of hardware and software’s for designing cyber physical system 2,3 70 70 L M H - - - - - - - - - - - -
CLO-5 : Come up with cost effective, reliable, robust and feasible designs for real world problems 2,3 70 70 L M H - - - - - - - - - - - -
CLO-6 : Design and implement real time systems and address the problems and limitations 3 90 80 - - H - M - - - M - - M H L -
DURATION (HOUR)
HUMAN IN THE LOOP CYBER PHYSICAL SYSTEMS
ENERGY CYBER PHYSICAL SYSTEMS SYMBOLIC SYNTHESIS FOR CYBER
PHYSICAL SYSTEMS
INTELLIGENT WIRELESS SENSOR NETWORKS IN CYBER PHYSICAL
SYSTEMS
HUMANS IN THE LOOP: A SIMPLE HANDS ON
S-1 SLO-1 The Evolution Of Cyber Physical Systems Introduction And Motivation
Symbolic Synthesis Introduction And Motivation
Intelligent Systems Motivation And Essentiality
A Sample Behavior Change Intervention App
SLO-2 Humans As Elements In Cyber Physical Systems
System Description And Operational Scenarios
Basic Techniques Of Symbolic Synthesis Wireless Sensor Networks The Sample App’s Base Architecture
S-2 SLO-1 Human Sensing And Virtual Communities Key Design Drivers And Quality Attributes
Problem Definition And Solving The Synthesis Problem
Deployment Of Wireless Sensor Networks In Cyber Physical Systems
The Android App And Server Set Up
SLO-2 Taxonomies For Human In The Loop CPS Key Design Drivers And Quality Attributes Problem Definition And Solving The Synthesis Problem
Deployment Of Wireless Sensor Networks In Cyber Physical Systems
Enhancing The Sample App With Human In The Loop Emotion Awareness
S-3 SLO-1 Humans As Set Of Sensors Key System Principles Asynchronous Design Primitives Intelligent Wireless Sensor Networks Choosing A Machine Learning Technique
SLO-2 Humans As Communication Nodes Performance Objectives In Terms Of Architectural Design
Construction Of Symbolic Models Comparison Between Wireless And Intelligent Wireless Sensor Networks
Implementing Emotion Awareness
S-4 SLO-1 State Inference And Human Nature
A Possible Way Forward Cyber Paradigm For Sustainable Socio Ecological Energy Systems
Construction Of Symbolic Models Information Security And Cyber Physical Systems Installing Android Studio
SLO-2 Humans As Processing Nodes Physics Based Composition Of CPS For An Socio Ecological Energy Systems
Advanced Techniques For Construction Of Symbolic Models
Attacks And Vulnerabilities In Cyber Physical System
Cloning The Android Project
S-5
SLO-1 Humans As Processing Nodes Physics Based Composition Of CPS For An Socio Ecological Energy Systems
Advanced Techniques For Construction Of Symbolic Models
Attack Resilient Design Deploying The Server Protocols
SLO-2 Actuation In CPS Dymonds Based Standards For CPS Of An Socio Ecological Energy Systems
Continuous Time Controllers And Software Tools
Attack Resilient Design Examples Installing The Software And Cloning The Server’s Project
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 63
S-6 SLO-1 Humans And Robots As Actuators
Dymonds Based Standards For CPS Of An Socio Ecological Energy Systems
Controller Timing And Control Design For Resource Efficiency
Example Application With Distinct Intelligence Level
Setting Up The Database And Deploying The Server On Tomcat
SLO-2 Powerline Communication Dymonds Based Standards For CPS Of An Socio Ecological Energy Systems
Computational Complexity And Time Reduction
Example Application With Smart Grid Handling Emotions On The Server
S-7 SLO-1
Technologies For Supporting Humans In Loop CPS
Interaction Variable Based Automated Modeling And Control
Less Frequent Sampling And Event Based Control
Example Application With Smart Field Monitoring
Creating The Web Interface
SLO-2 Technologies For Supporting Humans In Loop CPS
It Enabled Evolution Of Performance Objectives
Controller Software Structures Example Application With Variant Smartness
Creating The Servers Background Thread
S-8 SLO-1 Human In Loop Application Examples
It Enabled Evolution Of Performance Objectives
And Sharing Of Computing Resources CASE STUDY: Smart Space Systems Processing Incoming Emotions
SLO-2 Human In Loop Industry Examples Distributed Optimization Analysis And Simulation Of Feedback Control Systems
CASE STUDY: Smart Space Systems Handling New Emotion Interferences
S-9
SLO-1 Human In Loop Healthcare Examples Distributed Optimization Analysis And Simulation Of Feedback Control Systems
CASE STUDY: Smart City Systems Providing Positive Reinforcement
SLO-2 Human In Loop Smartphone And Social Networking
Summary And Open Challenges Analysis And Simulation Of Feedback Control Systems
CASE STUDY: Smart City Systems Creating A Motivational Dialog Box
Learning Resources
1. David Nunes, Jorge Sa Silva, And Fernando Boavida, A Practical Introduction To Human-In-The-Loop Cyber Physical Systems, 1st Edition, Wiley & IEEE PRESS, 2018.
2. Sherali Zeadally And Nafaa Jabeur, “Cyber Physical System Design With Sensor Networking Technologies,” 1st Edition IET Press, London, 2016.
3. Raj Rajkumar, Dionisio De Niz, And Mark Klein, “Cyber Physical Systems” , 1st Edition, Addison Wesley Publishers, 2017.
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)#
Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
40 % - 30 % - 30 % - 30 % - 30% - Understand
Level 2 Apply
40 % - 40 % - 40 % - 40 % - 40% - Analyze
Level 3 Evaluate
20 % - 30 % - 30 % - 30 % - 30% - Create
Total 100 % 100 % 100 % 100 % 100 %
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers
Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Mr. Athif Shah, Chairman, Abe Semicondutor, [email protected] 1. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] 1. Dr. Vivek Maik, SRMIST
2. Dr. Madan Kumar Lakshmanan, Senior Scientist, CEERI, [email protected] 2. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected]
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 64
Course Code
18ECE356T Course Name
MOBILE CYBER PHYSICAL SYSTEM Course
Category E Professional Elective
L T P C
3 0 0 3
Pre-requisite Courses
18ECE250T Co-requisite
Courses NIL
Progressive Courses
NIL
Course Offering Department Electronics and Communication Data Book / Codes/Standards NIL
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Learn Mobile Cyber Physical System Concepts 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
CLR-2 : Understand Mobile System Design For Embedded Applications
Leve
l of T
hink
ing
(Blo
om)
Exp
ecte
d P
rofic
ienc
y (%
)
Exp
ecte
d A
ttain
men
t (%
)
Eng
inee
ring
Kno
wle
dge
Pro
blem
Ana
lysi
s
Des
ign
& D
evel
opm
ent
Ana
lysi
s, D
esig
n, R
esea
rch
Mod
ern
Too
l Usa
ge
Soc
iety
& C
ultu
re
Env
ironm
ent &
Sus
tain
abili
ty
Eth
ics
Indi
vidu
al &
Tea
m W
ork
Com
mun
icat
ion
Pro
ject
Mgt
. & F
inan
ce
Life
Lon
g Le
arni
ng
PS
O -
1
PS
O -
2
PS
O –
3
CLR-3 : Design and understand green cloud computing
CLR-4 : Understand security and privacy threats in mobile networking
CLR-5 : Develop Deep Understanding On IoT and ubiquitous computing
CLR-6 : Gain Overall Understand Of The Real Time Systems For Industrial Applications
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Understand the architecture of mobile cyber physical system 1 80 70 H - - - - - - - - - - - - - -
CLO-2 : Design Mobile Cloud computing communication systems 1 75 70 - M - - - - - - - - - - - -
CLO-3 : Implement different practical real time systems with minimal supervision 3 75 70 - M H - - - - - - - - - - - H
CLO-4 : Develop Deep Understanding on selection of hardware and software’s for designing mobile cyber physical systems 3 75 70 - H - - - - - - - - - - - H
CLO-5 : Come up with cost effective, reliable, robust and feasible designs for real world problems 1 70 70 - M - - - - - - - - - - - - -
CLO-6 : Design and implement real time systems and address the problems and limitations 2 70 70 - M - - - - - - - - - - M - -
DURATION (HOUR)
MOBILE CLOUD COMPUTING GREEN CLOUD COMPUTING AND
RESOURCE ALLOCATION SECURITY AND PRIVACY THREATS WEB SERVICES IOT and UBIQUITOUS COMPUTING
S-1 SLO-1 Introduction, fundamental components Green cloud computing
Features of security and privacy issues in mobile clouds
Introduction to service oriented architecture
Internet of things introduction
SLO-2 Mobile computing Dimensions in algorithms of green clouds Main security and privacy problems Web services concepts Radio frequency identifcation technology
S-2 SLO-1 Wireless networks Creating an algorithm for green clouds Data over collection problems Web services architecture Wireless sensor networks technology
SLO-2 Main Techniques in Cloud Computing Sample Energy Aware Scheduling Algorithm
Data / Privacy Control Problems Specification of Web Services Sensor Technology
S-3 SLO-1 Mobile cloud computing architecture
Preemptable algorithm execution in mobile cloud systems
Trust management problems Simple object access protocol Sensor networks
SLO-2 Mobile cloud computing architecture Structure of cloud resource allocation mechanisms
Multi tenancy problems Representational state transfer Wireless sensor networks
S-4 SLO-1 Hybrid cloud resource manager
Steps of cloud resource allocation mechanisms
Threat taxonomy Javascript object notation Powerline communication
SLO-2 Manipulations of Cloud Resource Manager Messaging Methods: Push Pull Confidentiality, Integrity and Availability WS – Coordination IOT and Powerline Communication
S-5 SLO-1
Optimization Mechanisms of Hybrid Cloud Computing
Concept of Resource Allocation Model in Cloud Computing
Massive Data Mining Service Oriented Architecture (SOA) Ubiquitous Computing
SLO-2 Security Challenges and Solutions in Mobile Clouds
Resource Allocation Algorithms in Cloud Computing
Attach Interfaces Auditability Forensics and Legal Issues
SOA Understanding Services Ubiquitous Computing Properties
S-6 SLO-1 Security Challenges and Solutions in Mobile Clouds
Round Robin Algorithm Threat Models Basic Concepts Integrating SOA with Cloud Computing Tagging Sensing and Controlling
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 65
SLO-2 Optimization of Data Processing and Storage in Mobile Clouds
Round Robin Algorithm Example Insider Threats – Service Side and Customer Side
Web Service Business Process Execution Language
Tagging Sensing and Controlling
S-7 SLO-1 Cloud computing performance Cloud list scheduling algorithm
Outsider threats – attack methods and goals
Web service security and specifications Autonomous systems in ubiquitous computing
SLO-2 Two technical dimensions Cloud list scheduling algorithm example Crucial issues in outsider threats Ws-security framework Autonomous systems in ubiquitous computing
S-8
SLO-1 Basic task scheduling method Min-min scheduling algorithm Crucial security dimensions Big data and service computing Smart devices: components and services
SLO-2 Basic task scheduling method Min-min scheduling example Infrastructure security Overview of big data CASE STUDY: Digital Manufacturing / Industry 4.0: The Hannover Centre For Production Engineering (Pzh) Approach.
S-9
SLO-1 Example of Evaluation Modelizations CASE STUDY: Project Example on Green Cloud Computing and Resource Allocation
Network, Host and Application Layer Big Data Processing CASE STUDY: Digital Manufacturing / Industry 4.0: The Bosch Software Innovations Approach
SLO-2 CASE STUDY: Calculate Total Execution Time on Mobile CPS project
CASE STUDY: Project Example on Green Cloud Computing and Resource Allocation
CASE STUDY: Mobile Data Security and Storage, Identity and Access Management
CASE STUDY: Phase Reconfigurable Shuffle Optimization
CASE STUDY: Digital Manufacturing / Industry 4.0: The US Digital Manufacturing and Design Innovation Institute Approach
Learning Resources
1. Meikang Kiu , “Mobile Cloud Computing – Models, Implementation And Security” 5th Edition, CRC Press, 2015.
2. Dietmar P.F. Moller, “Computing Fundamentals In Cyber Physical Systems,” 1st Edition, Springer 2015 3. Edward D Lamie, “Real Time Embedded Multi Threading” , 2nd Edition, Newnes Elsevier Publication, 2016.
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)#
Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
40 % - 30 % - 30 % - 30 % - 30% - Understand
Level 2 Apply
40 % - 40 % - 40 % - 40 % - 40% - Analyze
Level 3 Evaluate
20 % - 30 % - 30 % - 30 % - 30% - Create
Total 100 % 100 % 100 % 100 % 100 %
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers
Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Mr. Athif Shah, Chairman, Abe Semicondutor, [email protected] 1. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] 1. Dr. Vivek Maik, SRMIST
2. Dr. Madan Kumar Lakshmanan, Senior Scientist, CEERI, [email protected] 2. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected]
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 66
B. Tech in Electronics and Communication Engineering (with specialization in Cyber Physical System)
2018 Regulations
Open Elective Courses (O)
Department of Electronics and Communication Engineering SRM Institute of Science and Technology
SRM Nagar, Kattankulathur – 603203, Kancheepuram District, Tamilnadu
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 67
Course Code 18ECO101T Course Name SHORT RANGE WIRELESS COMMUNICATION Course
Category O Open Elective
L T P C
3 0 0 3
Pre-requisite Courses
Nil Co-requisite
Courses Nil
Progressive Courses
Nil
Course Offering Department Electronics and Communication Engineering Data Book / Codes/ Standards Nil
Course Learning Rationale (CLR): Understand the concept of Short range Wireless Communication Learning Program Learning Outcomes (PLO)
CLR-1 : Overview of different modulation scheme and wireless system 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 CLR-2 : To understand the various components used to implement a short-range radio system.
Leve
l of T
hink
ing
(Blo
om)
Exp
ecte
d P
rofic
ienc
y (%
)
Exp
ecte
d A
ttain
men
t (%
)
Eng
inee
ring
Kno
wle
dge
Pro
blem
Ana
lysi
s
Des
ign
& D
evel
opm
ent
Ana
lysi
s, D
esig
n, R
esea
rch
Mod
ern
Too
l Usa
ge
Soc
iety
& C
ultu
re
Env
ironm
ent &
Sus
tain
abili
ty
Eth
ics
Indi
vidu
al &
Tea
m W
ork
Com
mun
icat
ion
Pro
ject
Mgt
. & F
inan
ce
Life
Lon
g Le
arni
ng
PS
O–1
: Pro
fess
iona
l
Ach
ieve
men
t
PS
O –
2: P
roje
ct M
anag
emen
t
Tec
hniq
ues
PS
O –
3: A
naly
ze &
Res
earc
h
CLR-3 : Analysis of the various kinds of transmitters and receivers used for Short range Wireless Communication.
CLR-4 : To know about regulations and standards of ISM band communications
CLR-5 : Design and analysis of short-range radio like UWB and Visible light.
Course Learning Outcomes (CLO): The purpose of this course is to introduce practically all aspects of radio communication including wave propagation, antennas, transmitters, receivers, design principles, telecommunication regulations
CLO-1 : To cover the various forms of signals used for information transmission and modulation, and overall wireless system properties.
2 80 70 L - - - - - - - - - - - - H -
CLO-2 : To present various component types that can be used to implement a short-range radio system. 2 85 75 - - M L - - - - - - - - H - -
CLO-3 : To describe the various kinds of transmitters and receivers. 2 75 70 - - H M - - - - - - - - - H -
CLO-4 : To covers regulations and standards of ISM band communications 2 85 80 M - - - - - - - - - - - M - - CLO-5 : To covers some of the most important new developments in short-range radio like UWB and Visible light. 2 85 75 - - L M - - - - - - - - - - H
Duration (hour) Wireless Systems Baseband Coding basics RF transceivers Wireless standards Optical wireless Technologies
9 9 9 9 9
S-1 SLO-1 Introduction to wireless systems Types of Antennas-Dipole, groundplane, loop RF Receivers- Introduction
Technical Background to the WPAN Concept - Regulation and Standardization Issues
Fundamentals of UROOF Technologies
SLO-2 Reasons for the Spread of Wireless Applications
Helical, Patch antennas RF Source-Frequency control European Consortium: Overview Conversion from RF to Optical Domain
S-2 SLO-1 Characteristics of Short-range Radio
Antenna Characteristics-Impedence, directivity and gain, Effective area
Modulation types Millimeter-Wave Applications and Services - PAN scenarios in the IST Magnet project
Conversion from Optical to RF Domain
SLO-2 Wireless Applications Polarization, Bandwidth, Antenna factor Amplifiers Typical LDR services connected to the IST-FP6 MAGNET project
Optical Microwave Mixing Used for UWB Over Systems
S-3 SLO-1
Elements of Wireless Communication Systems-Transmitter
Baseband Data Format and Protocol - Radio Communication Link Diagram
Impedance matching in transmitter and receivers
Frequency Regulation and Standardization Issues - Optional UM4 usage models issued from the IEEE802.15.3c TG
Integrated UROOF Transceiver (IUT)
SLO-2 Elements of Wireless Communication Systems-Receiver
Code Hopping Filtering Flexible antenna gain, 60 GHz regulation status for wireless transmissions.
Mixed Wireless-wired UROOF Channel, Carrier-to-noise Ratio
S-4 SLO-1
Wireless Local Area Networks (WLAN)-WIFI
Baseband Coding-Digital systems SAW band pass filter matching Channel Propagation Characterization and Modeling- 60 GHz Propagation Measurements
Laser and Photodetector Noise Baseline,
SLO-2 Network Architecture Wireless Microphone System Tuned Radio Frequency (TRF) Propagation Channel Characterization
Clipping Distortion Implication , Latency
S-5 SLO-1 Bluetooth Transceiver RF Frequency and Bandwidth-factors ASH Receiver Multipath Propagation Modeling Modelling the Propagation through the Fibre
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 68
SLO-2 Bluetooth Modes Propagation characteristics Super regenerative Receiver –Block diagram
France Telecom Propagation Channel Models
Analysis of UWB Technologies for UROOF- Comparing UWB Technologies for Radio-over- fibre
S-6 SLO-1 Zigbee Architecture, Frame Structure Modulation types
Super regenerative Receiver –Operation
MSK-Based System for LOS Gb/s Communications
MB-OFDM Over Multimode Fibre
SLO-2 Applications and conflicts Modulation for digital event communication Super heterodyne Receiver-Block diagram
System architecture for an MSK-based system to operate in a LOS channel.
All-optical Generation of Ultra-wideband Impulse Radio
S-7 SLO-1
Ultra-wideband Technology-Bit Sequence detection
Continuous Digital Communication Super heterodyne Receiver- Operation OFDM-Based System for NLOS Gb/s Communications
Operation Principles and Theoretical Approach
SLO-2 UWB Block Diagram Advanced Digital Modulation Direct Conversion Receiver- Block diagram
System architecture for an OFDM-based system to operate in a NLOS channel.
VLC Link –Transmitter
S-8 SLO-1 Wireless Modules-Japan,UK,USA Spread Spectrum-DHSS Direct Conversion Receiver- Operation System Design Aspects-Channel Plan The VLC Channel
SLO-2 Wireless Modules-Austria, Honeywell, Norway
Spread Spectrum-FHSS Digital Receivers-Software radio 60 GHz Channel Characteristics, Baseband Modulation: OFDM versus Single Carrier
Receiver, Modulation
S-9 SLO-1 FCC Regulations-Terms and definitions RFID-transceiver Software radio operation 60 GHz Analog Front-End Architectures Potential Applications
SLO-2 Nomenclature for defining Emission, modulation and transmission
Design issues for RFID Repeaters Multiple Antenna Technologies Challenges
Learning Resources
1. Alan Bensky, “Short range Wireless Communications-Fundamentals of RF system design and Applications”, Elsevier Inc, 2004
2. Antti V. Raisanen, Arto Lehto, “Radio engineering for wireless communication and sensor applications”, Artech House, 2003
3. Rolf Kraemer and Marcos Katz, “Short-range wireless communications emerging technologies and applications”, Wiley WWRF series, March 2009
4. Shlomi Arnon, John Barry, George Karagiannidis, Robert Schober, Murat Uysal, “Advanced Optical Wireless Communication Systems” , Cambridge University Press, 2012
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)#
Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
40 % - 30 % - 30 % - 30 % - 30% - Understand
Level 2 Apply
40 % - 40 % - 40 % - 40 % - 40% - Analyze
Level 3 Evaluate
20 % - 30 % - 30 % - 30 % - 30% - Create
Total 100 % 100 % 100 % 100 % 100 %
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers
Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Mr. Anuj Kumar, Bombardier Transportation, Ahmedabad, [email protected] 1. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] 1. Dr. J. Subhashini, SRM IST
2. Mr. Hariharasudhan - Johnson Controls, Pune, [email protected] 2. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected]
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 69
Course Code 18EC0102J Course Name ELECTRONIC CIRCUITS AND SYSTEMS Course
Category O Open Elective
L T P C
2 0 2 3
Pre-requisite Courses Nil Co-requisite Courses Nil Progressive
Courses Nil
Course Offering Department Electronics and Communication Engineering Data Book / Codes/ Standards
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Provide a basis for understanding semiconductor material, how a pn junction is formed and its principle of operation
1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
CLR-2 : Describe the basic structure, operation and characteristics of transistors BJTs and FETs, and discuss their use as a switch and an amplifier
Leve
l of T
hink
ing
(Blo
om)
Exp
ecte
d P
rofic
ienc
y (%
)
Exp
ecte
d A
ttain
men
t (%
)
Eng
inee
ring
Kno
wle
dge
Pro
blem
Ana
lysi
s
Des
ign
& D
evel
opm
ent
Ana
lysi
s, D
esig
n, R
esea
rch
Mod
ern
Too
l Usa
ge
Soc
iety
& C
ultu
re
Env
ironm
ent &
Sus
tain
abili
ty
Eth
ics
Indi
vidu
al &
Tea
m W
ork
Com
mun
icat
ion
Pro
ject
Mgt
. & F
inan
ce
Life
Lon
g Le
arni
ng
PS
O–1
: Pro
fess
iona
l Ach
ieve
men
t
PS
O –
2: P
roje
ct M
anag
emen
t
Tec
hniq
ues
PS
O –
3: A
naly
ze &
Res
earc
h
CLR-3 : Learn the basics of op-amp: the principle, operation, characteristics and fundamentally important circuits
CLR-4 : Describe and analyze the basic operation of sinusoidal oscillators and use a 555 Timer in an oscillator application.
CLR-5 : Learn the fundamentals of analog and digital communication, networking, radio transmission and mobile telephones
CLR-6 : Encourage the learner to assemble and test real circuits in the laboratory
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Understand the operation, characteristics, parameters and specifications of semiconductor diodes and demonstrate its important applications
1 80 70 L L - - - - - - - - - - - - -
CLO-2 : Review the transistor (BJT & FET) construction, operation, characteristics and parameters, as well as its application in amplification and switching.
1 80 70
L L - - - - - - - - - - - - -
CLO-3 : Identify different configurations of op-amp analyze the parameters of op-amp and observe the frequency response of operational-amplifier.
1 80 70 L L - - - - - - - - - - - - -
CLO-4 : Understand & demonstrate different applications based on operational-amplifier and special linear ICs 1 80 70 L L - - - - - - - - - - - - -
CLO-5 : Understand the basic concepts and techniques of telecommunication systems and networks 1 80 70 L L - - - - - - - - - - - - -
CLO-6 : Understand how circuit behavior can be studied with a computer, using a circuit simulation software 2 90 80 - - H - H - - - - L - M L - -
Learning Unit / Module 1
(12) Learning Unit / Module 2
(12) Learning Unit / Module 3
(12) Learning Unit / Module 4
(12) Learning Unit / Module 5
(12)
Duration (hour) Active Discrete Components &
Circuits – I Active Discrete Components &
Circuits – II Linear Integrated Circuits Oscillators and Timers Telecommunications
S-1 SLO-1 Conduction in semiconductors JFETs: Structure & Operation Introduction to Op-amp RC Phase-Shift oscillator Operation
Analog & Digital Communication: Stages in telecommunication systems
SLO-2 Conduction in diodes Characteristics & Parameters Basic op-amp and its characteristics & Design Carriers and Modulation
S-2 SLO-1 Basic operation of PN junction diode JFET Biasing (Voltage-Divider Biasing) op-amp modes Wein bridge Oscillator operation Carriers and Modulation SLO-2 VI Characteristics of diode CS-JFET Amplifier operation parameters & Design Pulse Modulation
S-3 SLO-1
Lab-1: VI Characteristics of PN Junction Diode
Lab-4: Design & Analysis of CE BJT Amplifier
Lab-7: Negative Feedback op-amp circuits
Lab-10: Analysis & Design of RC Oscillators
Lab-13: Demonstration of AM & FM SLO-2
S-4 SLO-1
SLO-2
S-5 SLO-1 Applications of diode: HWR & FWR MOSFETs: Structure
Op-amp circuits: Scale changer, adder, subtractor
LC oscillators operation: Hartley Oscillator
Pulse Modulation
SLO-2 Clippers & Clampers Operation HWR & FWR Colpitts Oscillator Digital Transmission, Frequency Division MultiplexingTime Division Multiplexing
S-6 SLO-1 Basic operation of Zener diode and its VI characteristics
Characteristics Clipper &Clamper 555 Timer IC: Basic Operation Networks: RS-232, circuit switching
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 70
SLO-2 Zener diode as a voltage regulator Parameters Log & Antilog amplifiers Astable Operation Message switching, TCP/IP
S-7 SLO-1
Lab-2: VI Characteristics of Zener Diode
Lab-5: Design & Analysis of CS-JFET Amplifier
Lab-8: Op-amp Circuits-I Lab-11: 555 Timer Operation & Applications
Lab-14: Demonstration of Pulse Modulation
SLO-2
S-8 SLO-1
SLO-2
S-9 SLO-1 BJTs: Structure & Operation MOSFET as an amplifier Instrumentation amplifier Monostable Operation Radio Transmission: Electromagnetic Spectrum, ground waves, sky waves
SLO-2 Characteristics & Parameters MOSFET as a switch Comparator Applications of 555 Timer antennas, directional transmissions,
S-10 SLO-1 CE BJT amplifier operation MOSFET Biasing (Voltage-Divider Biasing)
Comparator applications Applications of 555 Timer Transmitters, Receivers
SLO-2 Differential amplifier operation CS-MOSFET amplifier operation Schmitt trigger Voltage-Controlled Oscillators Mobile telephones
S-11 SLO-1
Lab-3: Applications of PN Junction diode and Zener diode
Lab-6: Design & Analysis of CS-MOSFET Amplifier
Lab-9: Op-amp Circuits-II Lab-12: VCO Operation Mini Project / Model Practical Examination
SLO-2
S-12 SLO-1
SLO-2
Learning Resources
1. Owen Bishop, “Electronic Circuits and Systems”, 4th edition, Elsevier, 2011.
2. Harry Kybett, Earl Boysen, “All New Electronics”, 3rd edition, Wiley, 2008.
3. Paul Scherz, “Practical Electronics for Inventors”, McGraw-Hill, 2000.
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)# Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
20% 20% 15% 15% 15% 15% 15% 15% 15% 15% Understand
Level 2 Apply
20% 20% 20% 20% 20% 20% 20% 20% 20% 20% Analyze
Level 3 Evaluate
10% 10% 15% 15% 15% 15% 15% 15% 15% 15% Create
Total 100 % 100 % 100 % 100 % -
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers
Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Mr. Anuj Kumar, Bombardier Transportation, Ahmedabad, [email protected] 1. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] 1. Mr. Manikandan AVM, SRM IST
2. Mr. Hariharasudhan - Johnson Controls, Pune, [email protected] 2. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected] 2. Dr. Rajesh Agarwal, SRM IST
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 71
Course Code
18ECO103T Course Name
MODERN WIRELESS COMMUNICATION SYSTEM Course
Category O Open Elective
L T P C
3 0 0 3
Pre-requisite Courses
Nil Co-requisite
Courses Nil
Progressive Courses
Nil
Course Offering Department Electronics and Communication Engineering Data Book / Codes/Standards Nil
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Learn to analyze the transmission of various wireless communication systems 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 CLR-2 : Understand the fundamentals of various networks in wireless communication
Leve
l of T
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ing
(Blo
om)
Exp
ecte
d P
rofic
ienc
y (%
)
Exp
ecte
d A
ttain
men
t (%
)
Eng
inee
ring
Kno
wle
dge
Pro
blem
Ana
lysi
s
Des
ign
& D
evel
opm
ent
Ana
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s, D
esig
n, R
esea
rch
Mod
ern
Too
l Usa
ge
Soc
iety
& C
ultu
re
Env
ironm
ent &
Sus
tain
abili
ty
Eth
ics
Indi
vidu
al &
Tea
m W
ork
Com
mun
icat
ion
Pro
ject
Mgt
. & F
inan
ce
Life
Lon
g Le
arni
ng
PS
O–1
: Pro
fess
iona
l
Ach
ieve
men
t P
SO
– 2
: Pro
ject
Man
agem
ent
Tec
hniq
ues
PS
O –
3: A
naly
ze &
Res
earc
h
CLR-3 : Understand the techniques involved in personal communication services.
CLR-4 : Introduce various wireless systems for 3G and future communication
CLR-5 : Learn to analyze wireless networks for short range communication
CLR-6 : Understand the Fundamentals, Techniques and Networks of Wireless Communication Systems
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Discuss the fundamentals of transmission in wireless systems 2,3 80 75 - - - H - - - - - - - - H
CLO-2 : Provide an overview of various approaches to communication networks 2,3 80 85 - - - H - - - - - - - - - - H
CLO-3 : Study the numerous different-generation technologies with their individual pros and cons 2,3 85 85 - - - H - - - - - - - - M - H
CLO-4 : Discuss about the principles of operation of the different access technologies like FDMA, TDMA, SDMA and CDMA and their pros and cons.
2,3 85 80 - - - H - - - - - - - - M - H
CLO-5 : Learn about the various mobile data services and short range networks. 2,3 85 80 - - - - - - - - - - - - - - H
CLO-6 : Gain knowledge on Fundamentals, Techniques and Networks of Wireless Communication Systems 2,3 85 80 - - - - - - - - - - - - H - -
Duration (hour)
Transmission Fundamentals Network Concepts Personal Communication Services 3G and Beyond Mobile Data Services and Short- Range
Network
9 9 9 9 9
S-1 SLO-1 Cellphone Generations Communication Networks
Personal communication Introduction, HSCSD, GPRS, D-AMPS, CDMA One, CDMA Two, Packet Data Systems
3G Introduction
Mobile Data Services Introduction Messaging, wireless web, WAP, site design Short-Range Wireless Networks: Unlicensed spectrum, WLANs, cordless telephony, IrDA, Bluetooth Smart Phones: Future phones, mobile OSs, smart phone applications.
SLO-2 1G and 2G LANs GSM IMT-2000 Introduction Data Services
S-2 SLO-1 2.5G MANs GSM IMT-2000 Messaging
SLO-2 3G WANs HSCSD IMT-2000 Wireless web
S-3 SLO-1 4G Transmission Introduction Circuit switching HSCSD W-CDMA Introduction WAP
SLO-2 4G Transmission Fundamentals Packet switching GPRS W-CDMA Site design
S-4 SLO-1 Time domain concepts ATM Cellular Networks Introduction GPRS CDMA 2000 Introduction Short-Range Wireless Networks
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 72
SLO-2 Frequency domain concepts Cells D-AMPS EDGE Unlicensed spectrum
S 5-6
SLO-1 Radio Media Duplexing D-AMPS EDGE WLANs
SLO-2
S-7 SLO-1 Analog Vs Digital Multiplexing CDMA Introduction Wi-Fi Introduction Cordless telephony
SLO-2 Channel capacity Voice coding CDMA One Wi-Fi IrDA
S-8 SLO-1 Transmission media Multiple Access Techniques: FDMA CDMA One WiMAX Introduction Bluetooth Smart Phones
SLO-2 Signaling Schemes TDMA, SDMA CDMA Two WiMAX Future phones
S-9 SLO-1 Carrier-based signaling, CDMA CDMA Two
OFDM
Mobile OSs
SLO-2 Spread-spectrum signaling Spectral efficiency Packet Data Systems MIMO Smart phone applications
Learning Resources
1. Simon Haykin, David Koilpillai, Michael Moher,” Modern Wireless Communication”, 1/e, Pearson Education, 2011
2. Rappaport T.S, “Wireless Communications: Principles and Practice”, 2nd edition, Pearson education.
3. Andrea Goldsmith, “Wireless Communications”, Cambridge University Press, Aug. 2005. 4. Andy Dornan, “The essential guide to wireless communications applications: from cellular
systems to Wi-Fi”, 2nd Edition, Prentice Hall, 2002
5. Ian F.Akyildiz, David M. Gutierrez Estevez, and Elias Chavarria Reyes, “ The evolution of 4G cellular systems: LTE advanced”, Physical communication, Volume 3, No. 4, pp. 217-298, Dec. 2010
6. William Stallings, “ Wireless Communication & Networking”, Pearson Education Asia, 2004 7. Andrea .F.Molisch, “Wireless communications”, 2nd edition, Wiley Publications.
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)# Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
30 % - 30 % - 30 % - 30 % - 30% - Understand
Level 2 Apply
40 % - 40 % - 40 % - 40 % - 40% - Analyze
Level 3 Evaluate
30 % - 30 % - 30 % - 30 % - 30% - Create
Total 100 % 100 % 100 % 100 % 100 %
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers
Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Mr. Anuj Kumar, Bombardier Transportation, Ahmedabad, [email protected] 1. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] 1. Dr. Sabitha Gauni, SRMIST
2. Mr. Hariharasudhan - Johnson Controls, Pune, [email protected] 2. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected]
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 73
Course Code 18ECO104J Course Name AUDIO AND SPEECH SIGNAL PROCESSING Course
Category O Open Elective
L T P C
2 0 2 3
Pre-requisite Courses
Nil Co-requisite
Courses Nil
Progressive Courses
Nil
Course Offering Department Electronics and Communication Engineering Data Book / Codes/Standards Nil
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : To explore about Speech signal processing 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
CLR-2 : To explore about the human auditory system
Leve
l of T
hink
ing
(Blo
om)
Exp
ecte
d P
rofic
ienc
y
(%)
Exp
ecte
d A
ttain
men
t (%
)
Eng
inee
ring
Kno
wle
dge
Pro
blem
Ana
lysi
s
Des
ign
& D
evel
opm
ent
Ana
lysi
s, D
esig
n,
Res
earc
h
Mod
ern
Too
l Usa
ge
Soc
iety
& C
ultu
re
Env
ironm
ent &
Sus
tain
abili
ty
Eth
ics
Indi
vidu
al &
Tea
m W
ork
Com
mun
icat
ion
Pro
ject
Mgt
. & F
inan
ce
Life
Lon
g Le
arni
ng
PS
O –
1: P
rofe
ssio
nal
Ach
ieve
men
t
PS
O –
2: P
roje
ct
Man
agem
ent T
echn
ique
s
PS
O –
3: A
naly
ze
&R
esea
rch
CLR-3 : Feature Extraction of Speech signal using Time characteristics
CLR-4 : Frequency characteristics of Speech signal CLR-5 : Provide a foundation for developing applications in this field.
CLR-6 : Understand the concept of speech processing both in time and frequency domain
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Understand the functioning of the human vocal and auditory systems in terms of signal processing 1 90 68 H H H - - - - M H
CLO-2 : Analyze the function of feature extraction in speech and audio signal processing using Time Domain Characteristics
2 85 67 H H M - - - - M H
CLO-3 : Understand the frequency characteristics of speech signal 2 85 68 H H M M - - - - H H
CLO-4 : Understand the Digital models for speech signal 1&2 85 65 H H H - - - - H M
CLO-5 : Understand the elements of music 2&3 85 66 H H H - - - - H H CLO-6: Understand Speech signal processing in time and frequency domain and their models. 1,2,3 85 68 H H M H - - - - M M
Duration (hour)
Learning Unit / Module 1
Basic Audio Processing Learning Unit / Module 2 Human auditory system
Learning Unit / Module 3
Speech Signal Analysis in Time Domain
Learning Unit / Module 4
Speech Signal Analysis in Frequency Domain
Learning Unit / Module 5
Speech and Audio processing applications
12 12 12 12 12
S-1 SLO-1 Introduction to Digital audio Human auditory system Speech signal analysis Short Time Fourier analysis Introduction to Speech recognition
SLO-2 Capturing and converting sound Human auditory system Speech signal analysis Short Time Fourier analysis Introduction to Speech recognition
S-2 SLO-1 Sampling of sound wave simplified model of cochlea Segmental, sub-segmental levels Filter bank analysis
Complete system for an isolated word recognition with vector quantization /DTW
SLO-2 Handling audio in MATLAB simplified model of cochlea Suprasegmental levels Formant extraction and Pitch extraction Complete system for an isolated word recognition with vector quantization /DTW
S-3 SLO-1
Lab 1: Read & write a speech signal, Record a speech signal, playback, convert into a wave file, plot the speech signal, and spectrogram plot.
Lab 4: Short-term energy of a speech signal
Lab 7: Estimation of pitch period using simplified inverse filter tracking (SIFT) algorithm
Lab 10: Phoneme-level segmentation of speech
Lab 13: Compute pitch period and fundamental frequency for speech signal
SLO-2
S-4 SLO-1
SLO-2
S-5 SLO-1 Normalization Sound pressure level and loudness Time domain parameters of speech signal Homomorphic speech analysis
Complete system for speaker identification, verification
SLO-2 Audio processing Sound pressure level and loudness Time domain parameters of speech signal Cepstral analysis of Speech Introduction to speech enhancement
S-6 SLO-1 Segmentation Sound intensity and Decibel sound levels
Methods for extracting the parameters Energy
Formant and Pitch Estimation Introduction to speech enhancement
SLO-2 Analysis of window sizing Sound intensity and Decibel sound levels Average ,Magnitude Linear Predictive analysis of speech Speech enhancement using spectral subtraction method
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 74
S-7 SLO-1
Lab 2: Convert into a wave file, plot the speech signal, and spectrogram plot
Lab 5: Short-time Fourier transform magnitude spectrum
Lab 8: Estimation of pitch period using harmonic product spectrum
Lab 11:To study the quantization and aliasing effect of speech signal
Lab 14: Short term speech analysis SLO-2
S-8 SLO-1
SLO-2
S-9 SLO-1 Visualization Concept of critical band Zero crossing Rate
Autocorrelation method, Covariance method
Introduction to Text to speech conversion
SLO-2 Sound generation Uniform filter bank , Non- uniform filter bank
Silence Discrimination using ZCR and energy
Solution of LPC equations Introduction to Musical instrument classification
S-10 SLO-1
Speech production mechanism, Charistics of speech
Mel scale and bark scale, Short Time Auto Correlation Function Durbin’s Recursive algorithm, Application of LPC parameters
Musical Information retrieval.
SLO-2 Understanding of speech Speech perception: vowel perception Pitch period estimation using Auto Correlation Function
Pitch detection using LPC parameters, Formant analysis
Sample Programs
S-11 SLO-1
Lab 3:Cepstrum smoothed magnitude spectrum
Lab 6: (i)Linear prediction magnitude spectrum, (ii) (ii) Estimation of formant frequencies using linear prediction
Lab 9: Pitch and duration modification using time-domain pitch synchronous overlap and add (TD-PSOLA) method
Lab 12:: Speech signal to symbol transformation using wavesurfer
Lab 15: Study of Praat SLO-2
S-12 SLO-1
SLO-2
Learning Resources
1. Ian McLaughlin, “Applied Speech and Audio processing, with MATLAB examples”, 1st Edition, Cambridge University Press, 2009
2. Ben Gold, Nelson Morgan, Dan Ellis, Wiley, “Speech and Audio Signal Processing: Processing and Perception of Speech and Music”, 2nd Edition, John Wiley & Sons, 01-Nov-2011.
3. Rabiner,B.H.Juang, “Fundamentals of Speech Recognition”, 2 nd Edition, Prentice-hall Signal Processing Series, April 1993
4. Ken Pohlmann, “Principles of Digital Audio”, 6th Edition, McGraw-Hill, 2007 5. A.R.Jayan, “Speech and Audio Signal Processing”, ISBN : 978-81-203-5256-8, PHI Learning Pvt. Ltd, 2016.
Learning Assessment
Bloom’sLevel of
Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)# Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
20% 20% 15% 15% 15% 15% 15% 15% 15% 15% Understand
Level 2 Apply
20% 20% 20% 20% 20% 20% 20% 20% 20% 20% Analyze
Level 3 Evaluate
10% 10% 15% 15% 15% 15% 15% 15% 15% 15% Create
Total 100 % 100 % 100 % 100 % 100 %
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Mr. Anuj Kumar, Bombardier Transportation, Ahmedabad, [email protected] 1. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] 1. Dr. S. Dhanalakshmi, SRMIST
2. Mr. Hariharasudhan - Johnson Controls, Pune, [email protected] 2. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected] 2. Mrs. K. Harisudha, SRMIST
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 75
Course Code 18ECO105T Course Name
UNDERWATER ACOUSTICS Course
Category
O
Open Elective
L T P C
3 0 0 3
Pre-requisite
Courses Nil
Co-requisite Courses
Nil Progressive
Courses Nil
Course Offering Department Electronics and Communication Engineering Data Book / Codes/Standards Nil
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Understand what is Sound Navigation and Ranging (SONAR) and how it can be used in underwater applications. 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
CLR-2 : Study about Ocean Acoustic Processing and sound wave propagation and analyze sea floor characteristics and ocean sounds.
Leve
l of T
hink
ing
(Blo
om)
Exp
ecte
d P
rofic
ienc
y (%
)
Exp
ecte
d A
ttain
men
t (%
)
Eng
inee
ring
Kno
wle
dge
Pro
blem
Ana
lysi
s
Des
ign
& D
evel
opm
ent
Ana
lysi
s, D
esig
n, R
esea
rch
Mod
ern
Too
l Usa
ge
Soc
iety
& C
ultu
re
Env
ironm
ent &
Sus
tain
abili
ty
Eth
ics
Indi
vidu
al &
Tea
m W
ork
Com
mun
icat
ion
Pro
ject
Mgt
. & F
inan
ce
Life
Lon
g Le
arni
ng
PS
O–1
: Pro
fess
iona
l Ach
ieve
men
t
PS
O –
2: P
roje
ct M
anag
emen
t T
echn
ique
s
PS
O –
3: A
naly
ze &
Res
earc
h
CLR-3 : Understand about Underwater reverberation and how types of noises affects the underwater acoustics signal data analysis.
CLR-4 : Study about Acoustic transducers.
CLR-5 : Know which transducers can be used for underwater applications.
CLR-6 : Understand the basic theory and signal processing application for underwater communication and navigation.
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Acquire in-depth knowledge and analyze on Sound Navigation and Ranging (SONAR) equations and it characteristics. L1 85 65 M - - - - - - - - - - M L
CLO-2 : Analyze Ocean Acoustic Processing and sound wave propagation. L2 85 65 M H H H H - - - - - - L H H H
CLO-3 : Acquire knowledge and analyze Underwater reverberation and various types of noises. L1&L2 85 65 M H H H - - - - - - L H M H
CLO-4 : Acquire knowledge on working of underwater Acoustic transducers. L1 85 65 H H H H H - - - - - - L H H H
CLO-5 : Gain knowledge and apply SONAR concepts for underwater applications. L1& L3 85 65 L H H - - - - - - - L H M H
CLO-6 : Understand the development and dynamics of underwater acoustic engineering L2 &L3 85 65 - - - - - - - - - - - - - - -
Duration (hour)
Learning Unit / Module 1 Sound Navigation and Ranging
(SONAR)
Learning Unit / Module 2 Ocean Acoustic Processing and sound
wave propagation
Learning Unit / Module 3 Reverberation and Noises
Learning Unit / Module 4 Acoustic Transduction
Learning Unit / Module 5 SONAR Application
9 9 9 9 9
S-1 SLO-1 Introduction to SONAR equation, Processing ocean sound-Sampling rules
Reverberation-Scattering, back scattering strength and target strength
Piezoelectric transducer-Introduction Echo sounder
SLO-2 Source Intensity, Source Directivity Spatial sampling and Temporal sampling Surface and bottom scattering Piezoelectric transducer-33-Mode longitudinal vibrator
Echo Sounder
S-2
SLO-1 Transmission loss Filter operations-Finite Fourier transformation Volume scattering, bottom scattering, reverberation target strength
Piezoelectric transducer-33-Mode longitudinal vibrator
Sub-bottom profiling
SLO-2 Transmission loss Filter operations-Time domain view of Band pass filtering. convolution operations, frequency domain
Calculation of reverberation for use in the sonar equation, Volume reverberation level
Electrostrictive transducers Fishing sonars
S-3 SLO-1 Target Strength
Gated Signals-Dependence of Spectrum on ping carrier periodicity
Reverberation frequency spread and Doppler gain potential-Power spectral density of a CW pulse
Electrostrictive transducers Side scan terrain mapping sonar
SLO-2 Reflection Intensity Loss Coefficient Power spectra of random signal-Signal having random characteristics, Spectral density,
Environmental frequency sampling Magnetostrictive transducers Side scan terrain mapping sonar
S-4
SLO-1 Sea-floor Loss, Radom signal simulations-Intensity spectral density, Spectral smoothing
Frequency spreading due to transmitter and receiver motion
Magnetostrictive transducers Acoustic positioning and navigation
SLO-2 Sea-surface Loss Matched filters and autocorrelation Frequency spreading due to target, important observation with respect to reverberation
Electostatic Transducers Acoustic positioning and navigation
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 76
S-5
SLO-1 Noise, Reverberation Sounds in the oceans-natural physical sounds and biological sounds
Noise-Ambient noise models Electostatic Transducers 3D Imaging Processing-data model
SLO-2 Active and Passive Sonar Equations Sound propagation in the ocean and underwater acoustic channel-Sound wave and vibration, velocity of sound
Ambient noise-seismic noise, ocean turbulence, shipping noise
Variable Reluctance Transducers 3D Imaging Processing-acquisition of 3D information
S-6
SLO-1 Passive Sonar Equations, Signal-to-Noise Ratio
Sound propagation in the ocean and underwater acoustic channel-Sound wave velocity of sound
Wave noise, thermal noise Variable Reluctance Transducers 3D Imaging Processing-matrix approach and real time systems
SLO-2 Signal Excess, Figure of Merit Wave and ray theories of underwater sound fields
Rain noise, temporal variability of ambient noise, depth effects of noise
Moving coil transducers 3D Imaging Processing-Image representation, Acoustic image processing
S-7
SLO-1 Active SONAR target strength Wave and ray theories of underwater sound fields
Under ice noise Moving coil transducers 3D Imaging Processing-Segmentation and reconstruction of underwater tubular structures
SLO-2 Active SONAR- reverberation, detection threshold
Wave and ray theories of underwater sound fields
Spatial coherence of ambient noise Equivalent circuits-Basics Circuit Resonance
3D Imaging Processing-Segmentation and reconstruction of underwater tubular structures
S-8 SLO-1
Active Sonar Sources- Source Level, Cavitation
Sound absorption in sea water and its characteristics
Self-noise-Flow noise Circuit Q and Bandwidth Acoustic communication-Cross attributes of the received signal
SLO-2 Near-Field Interactions Explosive Sources
Upper boundary of acoustic channel Self-noise – Flow noise Transducers as projectors-principle Acoustic communication-channel transfer function
S-9 SLO-1
Physics of Shock Waves in Wate, Bubble Pulses
Lower boundary of acoustic channel and its characteristics
Self noise-turbulent noise coherence Transducers as Hydrophones-principles of operations
Acoustic communication-combating multipath
SLO-2 Pros and Cons of Explosive Charges, Parametric Acoustic Sources
sound field in shallow water Self noise-strumming noise Transducers as Hydrophones-simplified equivalent circuit
Acoustic communication-diversity reception, equalization
Learning Resources
1. Richard P HODGES, “Underwater Acoustics – Analysis, Design and Performance of SONAR”, Wiley 1 edition2010, ISBN 978-0-470-68875-
2. Rodney F W Coates, “Underwater Acoustics Systems”, Macmillan New Electronics,Wiley, 1stedition , 1990, ISBN 978-0-333-42542-8
3. Robert S H Istepanian and MilicaStojanovic, “Underwater Acoustic Digital Signal Processing and Communication Systems”, Springer, 2002 edition, ISBN 978-1-4419-4882-3
4. Charles H Sherman, John L Butler, “Transducers and Arrays for Underwater Sound”, Springer; 2nd edition, 2016, ISBN-10: 0-387-32940-4 ISBN-13: 978-0387-32940-6
5. Qihu Li, “Digital Sonar Design in underwater acoustics: Principles and applications”, Springer, Zhejang University Press, 2012
6. Herman Medwin, Clarence S.Clay, “Fundamentals of Acoustical Oceanography”, Academic Press, 1998.
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)#
Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
40 % - 30 % - 30 % - 30 % - 30% - Understand
Level 2 Apply
40 % - 40 % - 40 % - 40 % - 40% - Analyze
Level 3 Evaluate
20 % - 30 % - 30 % - 30 % - 30% - Create
Total 100 % 100 % 100 % 100 % 100 % # CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers
Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Mr. Anuj Kumar, Bombardier Transportation, Ahmedabad, [email protected] 1. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] 1. Dr. S. Dhanalakshmi, SRMIST
2. Mr. Hariharasudhan - Johnson Controls, Pune, [email protected] 2. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected]
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 77
Course Code 18ECO106J Course Name PCB DESIGN AND MANUFACTURING Course
Category O Open Elective
L T P C
2 0 2 3
Pre-requisite Courses Nil Co-requisite Courses Nil Progressive
Courses Nil
Course Offering Department Electronics and Communication Engineering Data Book / Codes/ Standards
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Explore the terminologies of PCB design and Electronic components. 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 CLR-2 : Understand the design and other consideration involved in PCB design
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CLR-3 : Understand the PCB design consideration for special application circuits
CLR-4 : Design a PCB layout using CAD tool
CLR-5 : Explore various PCB manufacturing techniques
CLR-6 :
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Identify the various types of PCB and electronics components packaging 1 80 70 H L
CLO-2 : Select suitable design and consider appropriate parameters involved in PCB design 1,2 80 70 M L
CLO-3 : Apply the appropriate design rules in designing PCB for special application circuits 1,2 80 70 M L CLO-4 : Design and develop a PCB layout using CAD tool 1,2, 3 80 70 M M H
CLO-5 : Identify and select the required PCB manufacturing technology 1,2, 3 80 70 L H
CLO-6 :
Learning Unit / Module 1 Learning Unit / Module 2 Learning Unit / Module 3 Learning Unit / Module 4 Learning Unit / Module 5
Duration (hour) 12 12 12 12 12
S-1 SLO-1 Nomenclature of a Printed Circuit Board
PCB Design Considerations - Important Design Elements
Design Rules for Analog Circuits Schematic Capture - Introduction schematic capture tool
Image Transfer Techniques- Screen Printing, Pattern Transferring Techniques
SLO-2 Classification of Printed Circuit Boards PCB Design Considerations - Important Performance Parameters
S-2
SLO-1 Manufacturing of basic PCB - Single-and Double-sided Plated Through-holes
PCB Design Considerations - Mechanical Design Considerations
Design Rules for Digital Circuits
Schematic Capture - Simulation of simple electronic circuit
Image Transfer Techniques- Printing Inks, Photo Printing, Laser Direct Imaging (LDI)
SLO-2
Manufacturing of Multi-layer Boards - Flexible Boards, Challenges in modern PCB Design and Manufacture, PCB Standards
PCB Design Considerations - Mechanical Design Considerations
Schematic Capture - Schematic to layout transfer
Copper Clad Laminates - Properties of Laminates, Types of Laminates, Evaluation of Laminates
S-3 SLO-1
Study of electronic components- Passive electronic components
Design and analysis of RL and RC time constants. Schematic in CAD tool
Schematic and PCB Layout in CAD tool. Regulated power supply design.- Full wave rectifier circuit design with fixed voltage regulator
PCB Layout Design of single digit pulse counter using PCB design tool.
Mini Project - PCB Layout Design of electronic turn ON/OFF timer using IC555 using PCB design tool.
SLO-2
S-4 SLO-1
SLO-2
S-5 SLO-1
Types, Symbols, Packaging shapes and terminal details of Electronic Components –Resistors, Thermistors Capacitors, Inductors
PCB Design Considerations - Electrical Design Considerations
Design Rules for High Frequency Circuits PCB Layout Design - Conception Level Introduction
Etching Techniques – wet Etching chemicals
SLO-2 Diodes, Light Emitting Diodes (LED), Photodiode,
PCB Design Considerations - Conductor Patterns, Component Placement Rules
Design Rules for Fast Pulse Circuits PCB Layout Design - Specifying Parts, Packages and Pin Names, Libraries
Etching Techniques - Mechanical Etching
S-6 SLO-1 Transistors, Field-effect Transistors, Insulated Gate Bipolar Transistor (IGBT), Thyristor
Fabrication and Assembly Considerations Design Rules for Microwave Circuits PCB Layout Design - Checking foot prints of the components, Part list, Net list, Making Net list Files
PCB Assembly Process - Through-hole
S-7 SLO-1 Design and analysis of RLC circuits. Schematic in CAD tool
Schematic and PCB Layout in CAD tool. Mini Project - Manufacture the PCB for electronic turn ON/OFF timer using SLO-2
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 78
S-8 SLO-1 Study of electronic components- active devices, analog and digital integrated circuits (IC)
Regulated power supply design. -Full wave rectifier circuit design with fixed voltage regulator
PCB Design of single digit pulse counter: Schematic and PCB layout using PCB design tool.
IC555and construct and test the designed circuit.
SLO-2
S-9 SLO-1 Digital Integrated Circuits, Random Access Memory
Environmental Factors, Cooling Requirements
Design Rules for High-density Interconnection Structures
PCB Layout Design - Mounting Holes, Adding Text, PCB Layout
PCB Assembly Process - Surface Mount, Mixed Technologies
SLO-2 Read Only Memory Packaging Density
S-10 SLO-1 Microcontrollers, Surface Mount Devices Layout Design
Electromagnetic Interference/Compatibility (EMI/EMC)
PCB Layout Design - DRC, Pattern Transfer, Layout printing
PCB Assembly Process - Soldering SLO-2 Transformer, Relays, Connectors
S-11 SLO-1 Study of testing and measuring Instruments: Logic analyzer, spectrum analyzer, IC tester (Analog and Digital), LCR meters
PCB Layout Design - of RL, RC and RLC circuits
Schematic and PCB Layout in CAD tool. Regulated power supply design. Full wave rectifier circuit design with fixed voltage regulator
Mini Project - PCB Layout Design of electronic turn ON/OFF timer using IC555 using PCB design tool.
Mini Project - Manufacture the PCB for electronic turn ON/OFF timer using IC555and construct and test the designed circuit.
SLO-2
S-12 SLO-1
SLO-2
Learning Resources
1. Raghbir Singh Khandpur, “Printed Circuit Boards: Design, Fabrication, and Assembly” McGraw-
Hill Electronic Engineering, 2006.
2. Charles A. Harpe, “High Performance Printed Circuit Boards”, McGraw Hill Professional, 2000.
3. Bruce R. Archambeault, James Drewniak, “PCB Design for Real-World EMI Control”, Volume 696 of
The Springer International Series in Engineering and Computer Science, Springer Science & Business
Media, 2013.
4. Kraig Mitzner, “Complete PCB Design Using OrCAD Capture and PCB Editor”, Newnes/Elsevier, 2009.
5. Douglas Brooks “Signal Integrity Issues and Printed Circuit Board Design”, Prentice Hall PTR, 2003.
6. Mark I. Montrose “Printed Circuit Board Design Techniques for EMC Compliance : A handbook for
designers” Wiley, 2 Edition, 2015.
7. Esim open source tool : http://esim.fossee.in/ 8. TINA/Orcad User manual
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)# Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
20% 20% 15% 15% 15% 15% 15% 15% 15% 15% Understand
Level 2 Apply
20% 20% 20% 20% 20% 20% 20% 20% 20% 20% Analyze
Level 3 Evaluate
10% 10% 15% 15% 15% 15% 15% 15% 15% 15% Create
Total 100 % 100 % 100 % 100 % -
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers
Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Mr. Anuj Kumar, Bombardier Transportation, Ahmedabad, [email protected] 1. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] 1. Dr. P. Eswaran, SRM IST
2. Mr. Hariharasudhan - Johnson Controls, Pune, [email protected] 2. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected]
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 79
Course Code
18ECO107T Course Name
FIBER OPTICS AND OPTOELECTRONICS Course
Category O Open Elective
L T P C
3 0 0 3
Pre-requisite Courses
Nil Co-requisite
Courses Nil
Progressive Courses
Nil
Course Offering Department Electronics and Communication Engineering Data Book / Codes/Standards Nil
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Analyze the basic laws and theorems of light associated with the optical fiber communication and the classification of optical fibers
1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
CLR-2 : Address concepts related to transmission characteristics such as attenuation and dispersion.
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CLR-3 : Explore the fundamentals of optoelectronics display devices, Sources and Detectors
CLR-4 : Gain to information on Optical modulators and amplifiers
CLR-5 : Illustrate the integration methods available for optoelectronic circuits and devices CLR-6 : Utilize the basic optical concepts applied in various engineering problems and identify appropriate solutions
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Review the basic theorems related to fiber optic communication, and attain knowledge of types of optical fibers 2 80 70 H H - - - - - - - - - - - H
CLO-2 : Understand the optical signal distortion factors in optical fiber communication 2 85 75 H - M - - - - - - - - - - - M
CLO-3 : Familiarize the principle and operation of various display devices, light sources and detectors 2 75 70 H M M - - - - - - - - - - - L
CLO-4 : Acquire knowledge of various optoelectronic modulators and amplifiers 2 85 80 H - M - - - - - - - - - - - H CLO-5 : Understand the various optoelectronic integrated circuits 2 85 75 H - M L - - - - - - - - - - L
CLO-6: Acquire fundamental concepts related to optical communication and optoelectronic devices 2 80 75 H M M L - - - - - - - - - - H
Duration (hour)
Learning Unit / Module 1
Introduction to Optical Fibers
Learning Unit / Module 2
Transmission Characteristics of Optical Fibers
Learning Unit / Module 3
Display Devices, Light Sources and Detection Devices
Learning Unit / Module 4
Optoelectronic Modulators and Switching Devices
Learning Unit / Module 5
Optoelectronic Integrated Circuits
9 9 9 9 9
S-1
SLO-1 Evolution of fiber optic system Attenuation – Absorption, Attenuation units Display devices – Photo luminescence Analog and Digital Modulation Optoelectronic integrated circuits - Introduction
SLO-2 Elements of an optical fiber transmission link
Attenuation – Scattering losses Cathode luminescence Electro optic modulators – Electro optic effect – Longitudinal electro optic modulator
Need for Integration - Hybrid and Monolithic Integration
S-2 SLO-1
Elements of an optical fiber transmission link
Attenuation – Bending losses, microbending and macro bending losses
Electro luminescence Electro optic modulators – Transverse electro optic modulator
Hybrid and Monolithic Integration
SLO-2 Advantages of fiber optic system Attenuation - Core cladding losses Injection luminescence Acousto optic modulators – Transmission type – Raman Nath modulator
Materials and processing of OEICs
S-3 SLO-1 Characteristics and behavior of light Signal distortion in optical waveguides Light source materials
Acousto optic modulators – Reflection type – Bragg modulator
Application of optoelectronic integrated circuits
SLO-2 Total internal reflection Types of dispersion-Intramodal and Intermodal dispersion
Surface emitting LEDs Solving Problems Slab and Strip Waveguides
S-4
SLO-1 Acceptance angle Material dispersion Edge emitting LEDs Optical switching and logic devices – self-electro-optic-device
Integrated transmitters and receivers – Front end photo receivers
SLO-2 Numerical aperture, Critical angle Material dispersion, Waveguide dispersion Quantum efficiency and LED power – Internal quantum efficiency derivation
Optical switching and logic devices – Bipolar controller modulator
Integrated transmitters and receivers – photoreceiver noise and bandwidth considerations
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 80
S-5
SLO-1 Solving Problems Waveguide dispersion Quantum efficiency and LED power – External quantum efficiency and total LED power
Optical switching and logic devices- tunable threshold logic gate – Switching speed and energy.
Integrated transmitters and receivers – PIN-HBT photoreceivers
SLO-2
Solving Problems Signal distortion in single mode fibers Solving Problems Optical Amplifiers – General applications of optical amplifiers
Integrated transmitters and receivers – OEIC transmitters – equivalent circuit for integrated receivers
S-6 SLO-1 Ray optics Polarization mode dispersion Semiconductor laser diode
Semiconductor optical amplifiers – Basic configuration
Integrated transmitters and receivers – Complex circuits and arrays
SLO-2 Types of rays Polarization mode dispersion, Intermodal dispersion
Modes and threshold condition Semiconductor optical amplifiers – Optical gain - Limitations
Integrated transmitters and receivers - optical control and microwave oscillators
S-7 SLO-1 Optical fiber modes Intermodal dispersion Photo detection principle
Erbium doped fiber amplifiers – energy level diagram and amplification mechanism
Guided wave devices – Waveguide and couplers
SLO-2 Optical fiber configurations Solving Problems PIN Photodiode Erbium doped fiber amplifiers – EDFA configuration
Guided wave devices – Active guided wave devices
S-8 SLO-1 Single mode fibers Solving Problems PIN photodiode - Avalanche Photodiode Solving Problems
Guided wave devices – Mach Zehnder Interferometers
SLO-2 Multimode Fibers Pulse Broadening in Graded Index Waveguides
Avalanche Photodiode Solving Problems Active couplers
S-9
SLO-1 Step Index Fibers Mode Coupling Noise mechanism in photodetectors Fiber Raman Amplifiers – Configuration – Forward pumping
Active Couplers
SLO-2 Graded Index Fibers Design Optimization of Single Mode Fibers Solving Problems Fiber Raman Amplifiers – Backward pumping
Active Couplers
Learning Resources
1. Gerd Keiser, “Optical Fiber Communications”, 5th Edition, McGraw Hill Education (India), 2015. 2. Khare R P, “Fiber Optics and Optoelectronics”, Oxford University Press, 2014.
3. J. Wilson and J. Hawkes, “Optoelectronics – An Introduction”, Prentice Hall, 1995. 4. Pallab Bhattacharya, “Semiconductor Optoelectronic Devices”, Prentice Hall of India Pvt. Ltd, 2006.
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)#
Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
40 % - 30 % - 30 % - 30 % - 30% - Understand
Level 2 Apply
40 % - 40 % - 40 % - 40 % - 40% - Analyze
Level 3 Evaluate
20 % - 30 % - 30 % - 30 % - 30% - Create
Total 100 % 100 % 100 % 100 % 100 % # CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Mr. Anuj Kumar, Bombardier Transportation, Ahmedabad, [email protected] 1. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] 1. Dr. S. Sathiyan, SRMIST
2. Mr. Hariharasudhan - Johnson Controls, Pune, [email protected] 2. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected]
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 81
Course Code
18ECO108J Course Name
EMBEDDED SYSTEM DESIGN USING ARDUINO Course
Category O Open elective courses
L T P C
2 O 2 3
Pre-requisite Courses
Nil Co-requisite
Courses Nil
Progressive Courses
Nil
Course Offering Department ECE Data Book / Codes/Standards Nil
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Get to know about ARDUINO hardware details and environment 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 CLR-2 : To understand the core elements of ARDUINO programming language
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CLR-3 : Create insights to the concepts of serial communication
CLR-4 : To use common input and output devices
CLR-5 : Apply the ARDUINO programming into real time applications
CLR-6 :
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Analyze the programming skill 2 80 70 H - - - - - - - - - - - H H
CLO-2 : Apply the real time data’s into digital 2 85 75 H H H H H - - - H - H - - H H
CLO-3 : Interact with almost many devices 2 75 70 H - H H H - - - H - H - H H - CLO-4 : Learn techniques to handle timer delays and IO devices 2 85 80 H H H H H - - - H - H - H H -
CLO-5 : Use and modifying the existing libraries 2 85 75 H - H H H - - - H - H - H H -
CLO-6 :
Duration (hour)
12 12 12 12 12
S-1 SLO-1 Introduction to arduino platform Introduction To Arduino C Analog And Serial Communication IO Programming Case Studies
SLO-2 Block diagram Arduino C Data Types . Introduction To Analog Communication Introduction To Timer/Counters Wireless Communication Using Zigbee
S-2 SLO-1 AT mega 328p architecture Decision Making in C Pulse Width Modulation Introduction To Timer/Counters Bluetooth
SLO-2 AT mega 328p architecture Decision Making in C RS232
Timer programming Robotics -Motor And Sensor
S 3-4 SLO-1 Lab 1 Getting Started With Adriano
Lab 4 -Sensor Interfacing For Temperature Monitoring
Lab 7: Actuators – Stepper Motor Lab10:Interrupt Programming Lab 13:Mini Project
SLO-2 CCS And AVR Studio 7 Blinking Led Lab 4 -Sensor Interfacing For Displacement Measurement
Lab 7: Actuators – Stepper Motor Lab10:Interrupt Programming Lab 13:Mini Project
S-5 SLO-1 Pin function
Program Loops in C I2C
Timer programming Security-RFID, Infrared
SLO-2 Overview of main features-I/O ports Functions in C
I2C Timer programming
Security-RFID, Infrared
S-6 SLO-1
Features-timers,interrupts Introduction to Pointers I2C Timer programming
Bio medical application SLO-2
S 7-8 SLO-1 Lab 2 GPIO LED
Lab 5: PWM BASED SERVO MOTOR INTERFACING
Lab 8: DC MOTOR Lab11:Watch Dog Timer Lab14:Model Practical
SLO-2 Switch Based Led Control Lab 5: PWM Based Servo Motor Interfacing
Lab 8: DC MOTOR Lab11:Watch Dog Timer Lab14:Model Practical
S-9 SLO-1 Features-PWM,SERIAL PORT Using Pointers Effectively SPI Protocol Interrupts
Bio medical application
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 82
SLO-2 Features-ADC Structures, Unions, and Data Storage SPI Protocol
Interrupt programming Bio medical application
S-10 SLO-1
Introduction to Arduino IDE Arduino Libraries Interfacing with sensors
External interrupt GPS Navigation
SLO-2 Writing ,saving,compiling with IDE. Arduino Libraries
Interfacing with sensors External interrupt GPS Navigation
S11-12 SLO-1 Lab 3:DISPLAY INTERFACE-7 SEGMENT
Lab 6:SERIAL COMMUNICATION Lab 9: Repeat/Revision Of Experiments Lab 12 : I2C Lab:15 University Practical
SLO-2 LCD 16x2 Matrix Lab 6:Serial Communication Lab 9: Repeat/Revision Of Experiments
Lab 12: I2C Lab:15 University Practical
Learning Resources
1. Michael-Margolis,Arduino-Cookbook., Revised edition, O’Reilly,1st edition, 2011 2. D.Dale.Wheat, Arduino.Internals, TIA publication, 5th edition, 2011
3. James M. Fiore, Embedded Controllers Using C and Arduino, ARDUINO open source community, 2018 4. Jack Purdum ,Beginning C for Arduino , Apress, 2012
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)# Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
20% 20% 15% 15% 15% 15% 15% 15% 15% 15% Understand
Level 2 Apply
20% 20% 20% 20% 20% 20% 20% 20% 20% 20% Analyze
Level 3 Evaluate
10% 10% 15% 15% 15% 15% 15% 15% 15% 15% Create
Total 100 % 100 % 100 % 100 % -
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers
Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Mr. Anuj Kumar, Bombardier Transportation, Ahmedabad, [email protected] 1. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] 1.Mrs. S. Suhasini,, SRM IST
2. Mr. Hariharasudhan - Johnson Controls, Pune, [email protected] 2. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected]
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 83
Course Code
18ECO109J Course Name
EMBEDDED SYSTEM DESIGN USING RASPBERRY PI Course
Category O Open Elective
L T P C
2 0 2 3
Pre-requisite Courses
Nil Co-requisite
Courses Nil
Progressive Courses
Nil
Course Offering Department Electronics and Communication Engineering Data Book / Codes/Standards Nil
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Understanding the programing of python for Raspberry Pi 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 CLR-2 : Applying python programming on GPIO and interfacing motors using Raspberry Pi
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Mod
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Sus
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Eth
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Indi
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Pro
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Life
Lon
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men
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PS
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2: P
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anag
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s
PS
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3: A
naly
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Res
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h CLR-3 : Applying python programming on GPIO switch and keyboard
CLR-4 : Create insights to the concepts and programming of motion detection ,GPS programming, light sensor ,gas detection
CLR-5 : Analyze and understand the working principle and data sheet of temperature sensor, gas sensor ,ADC, ultrasonic rangefinder, Acceleration and light sensor
CLR-6 : Utilize the technology of node js ,cloud service and MQTT Protocol for moving sensor data to web
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Apply python for Raspberry Pi 2 80 70 H H - - H - - - - - - - H - -
CLO-2 : Analyze data sheet and functioning of sensors 2 85 75 H H H H H - - - - - - - - - H
CLO-3 : Apply python programming on GPIO of Raspberry Pi and interfacing of sensor 2 75 70 H H H H - - - - - - - - H - -
CLO-4 : Apply python programming on GPIO of Raspberry Pi to interfacing of actuators 2 85 80 H H H H H - - - - - - - H - - CLO-5 : Apply python programming on GPIO of Raspberry Pi to interfacing input and display device 2 85 75 H - H H - - - - - - - - H - -
CLO-6 : Apply technology of node js ,cloud service and MQTT Protocol for IOT application 2 80 70 H - H - H - - - - - - - - - H
Duration (hour)
Learning Unit / Module 1
Basic python programming
Learning Unit / Module 2
Programming interrupts –Motor control, switches and keyboard interface
Learning Unit / Module 3
Sensor interface and programming
Learning Unit / Module 4
Temperature sensor and display interface programming
Learning Unit / Module 5
Publishing sensor data on web service
12 12 12 12 12
S-1
SLO-1
Python Basics- Editing Python Programs with IDLE, Variables, displaying Output, Reading User Input , Arithmetic, Creating Strings
Programming with Interrupts Detecting Movement-PIR sensor Measuring Temperature Using a Digital Sensor
publish sensor data on web service-building a home security dash board
SLO-2
Concatenating (Joining) Strings, Converting Numbers to Strings, Converting Strings to Numbers ,Find the Length of a String, Find the Position of One String Inside Another, Extracting Part of a String, Replacing One String of Characters with Another Inside a String ,Converting a String to Upper- or Lowercase
Programming with Interrupts Data sheet analysis of PIR sensor Data sheet analysis Digital Temperature Sensor
publish sensor data on web service-building a home security dash board
S-2
SLO-1 Running Commands Conditionally, Comparing Values, Logical Operators,
Controlling GPIO Outputs Using a Web Interface
Adding GPS to the Raspberry Pi Measuring Distance-ultrasonic rangefinder MQTT Protocol
SLO-2
Repeating Instructions an Exact Number of Times ,Repeating Instructions Until Some Condition Changes , Breaking Out of a Loop, Defining a Function in Python
Controlling GPIO Outputs Using a Web Interface
Data sheet analysis of GPS Data sheet analysis ultrasonic rangefinder MQTT Protocol- installation and setting account ,token creation ,reading sensor data and pushing to thingsboard
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 84
S-3-4 SLO-1 Lab 1: Arithmetic and string Lab 7: Programming on interrupts Lab 13: Programming on PIR sensor
Lab 19: Programming on Digital Temperature Sensor
Lab 25: Publish sensor data on web service
SLO-2 Lab 2: Loop Lab 8: Programming on Web Interface Lab 14: Programming on GPS Lab 20: Programming on ultrasonic rangefinder
Lab 26: Publish sensor data on web service
S-5
SLO-1
Creating a List , Accessing Elements of a List, Find the Length of a List , Adding Elements to a List , Removing Elements from a List,
Controlling Servo Motors using PWM Using Resistive Sensors Logging to a USB Flash Drive basic of java scripts –node.js
SLO-2
Creating a List by Parsing a String, Iterating over a List, Enumerating a List, Sorting a List, Cutting Up a List. Applying a Function to a List
Controlling the Speed of a DC Motor Measuring Light Logging to a USB Flash Drive Modules-HTML module
S-6 SLO-1
Creating a Dictionary ,Accessing a Dictionary, Removing Things from a Dictionary,
Controlling the Direction of a DC Motor Detecting Methane Using a Four-Digit LED Display Modules –file –event
SLO-2 Iterating over Dictionaries Using a Unipolar Stepper Motor Data sheet analysis of gas sensor Displaying Messages on an I2C LED matrix with data sheet discussion
Modules –file –event
S-7-8 SLO-1 Lab 3: Program on list Lab 9: Programming on Stepper Motor Lab 15: Programming on light sensor
Lab 21: Programming on Four-Digit LED Display
Lab 27: Programming on node js HTML module
SLO-2 Lab 4: Program on Dictionary Lab 10: Programming on DC Motor Lab 16: Programming on Gas sensor Lab 22: Programming on I2C LED matrix
Lab 28: Programming on node js file and event module
S-9 SLO-1
Controlling Hardware-Connecting an LED-Controlling the Brightness of an LED
Using a Bipolar Stepper Motor Measuring a Voltage using MCP3008 And data sheet of MCP3008
Displaying Messages on an Alphanumeric LCD
LED blinking using node.js
SLO-2 a Buzzing Sound Building a Simple Robot Rover Using Resistive Sensors with an ADC Displaying Messages on an Alphanumeric LCD
LED blinking using node.js
S-10 SLO-1
Switching a High-Power DC Device Using a Transistor
Digital Inputs-Connecting a Push Switch-Toggling with a Push Switch-Using a Two-Position Toggle or Slide Switch
Measuring Temperature with an ADC Cloud service for IOT building java script client using MQTT broker
SLO-2 Switching a High-Power Device Using a Relay
Using a Rotary (Quadrature) Encoder and Using a Keypad
Measuring Acceleration and data sheet discussion of Acceleration sensor
Cloud service for IOT building java script client using MQTT broker
S-11, 12
SLO-1 Lab 5: LED blinking and Brightness control Lab 11: Programming on Switch Lab 17: Programming on ADC
Lab 23: Programming on an Alphanumeric LCD
Lab 29: Programming on LED blinking using node.js
SLO-2 Lab 6: Switching a High-Power DC Device Lab 12: Programming on Keypad
Lab 18: Programming on Measuring Acceleration
Lab 24: Programming on an Alphanumeric LCD
Lab 30: Building java script client using MQTT broker
Learning Resources
1. Simon Monk, “Raspberry Pi Cookbook”, O’Reilly Media, Inc, 2014. 2. Volker Ziemann, “A Hands-On Course in Sensors Using the Arduino and Raspberry Pi, CRC
Press, 2018.
3. Colin Dow, “Internet of Thing: Programming Projects - Build modern IoT solutions with the Raspberry Pi 3 and Python”, packtpub 2018.
4. https://thingsboard.io/docs/ 5. https://www.w3schools.com/nodejs/nodejs_raspberrypi_blinking_led.asp
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)# Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
20% 20% 15% 15% 15% 15% 15% 15% 15% 15% Understand
Level 2 Apply
20% 20% 20% 20% 20% 20% 20% 20% 20% 20% Analyze
Level 3 Evaluate
10% 10% 15% 15% 15% 15% 15% 15% 15% 15% Create
Total 100 % 100 % 100 % 100 % 100 %
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 85
Course Designers Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Mr. Anuj Kumar, Bombardier Transportation, Ahmedabad, [email protected] 1. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] 1. Dr. P. Vijayakumar, SRMIST
2. Mr. Hariharasudhan - Johnson Controls, Pune, [email protected] 2. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected]
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 86
Course Code
18ECO110J Course Name
3D PRINTING HARDWARE AND SOFTWARE Course
Category E Professional Elective
L T P C
2 0 2 3
Pre-requisite
Courses Nil
Co-requisite Courses
Nil Progressive
Courses Nil
Course Offering Department Electronics and Communication Engineering Data Book / Codes/Standards Nil
Course Learning Rationale (CLR): The purpose of learning this course is to:
Learning
Program Learning Outcomes (PLO)
CLR-1 : Understand the tools available for 3D printing 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
CLR-2 : Familiarize with 3D design software and hardware
Leve
l of T
hink
ing
(Blo
om)
Exp
ecte
d P
rofic
ienc
y (%
)
Exp
ecte
d A
ttain
men
t (%
)
Eng
inee
ring
Kno
wle
dge
Pro
blem
Ana
lysi
s
Des
ign
& D
evel
opm
ent
Ana
lysi
s, D
esig
n, R
esea
rch
Mod
ern
Too
l Usa
ge
Soc
iety
& C
ultu
re
Env
ironm
ent &
Sus
tain
abili
ty
Eth
ics
Indi
vidu
al &
Tea
m W
ork
Com
mun
icat
ion
Pro
ject
Mgt
. & F
inan
ce
Life
Lon
g Le
arni
ng
PS
O–1
: Pro
fess
iona
l Ach
ieve
men
t
PS
O –
2: P
roje
ct M
anag
emen
t T
echn
ique
s
PS
O –
3: A
naly
ze &
Res
earc
h CLR-3 : Understand the 3D design criteria and its limitations. CLR-4 : Learn the contemporary technology available for 3D design and printing
CLR-5 : Understand various post processing methods involved in 3D printing technology
CLR-6 : Develop the skillset on 3D component design and development using contemporary commercial software and hardware available.
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Apply the 3D printing tools for components design 1 80 60 M M
CLO-2 : Able to optimistically select the 3D design software and hardware for the given problem 1 80 60 M H
CLO-3 : Capability to solve 3D design components design problems 2 75 60 M M M CLO-4 : Choose the contemporary technology available for 3D design and printing 3 80 60 M M L
CLO-5 : Apply various post processing methods involved in 3D printing technology 2 80 60 H
CLO-6 : Ability to develop the skillset on 3D component design and development using contemporary commercial software and hardware available.
2 80 60
M M
Duration (hour)
Introductions to 3D design tools Three-dimensional (3D) Modeling 3D Design Fundamentals and Projects 3D Printing and its Technologies Post Processing - Product Visualization and Print Cleaning
S-1
SLO-1 Introduction to Maya GUI - Object creation workflow, Constructing object primitives to scale and with accuracy
An overview of CAD software packages - Introduction to Fusion 360 - Drawing based workflow, Drawing constraints - Surfacing operations.
The good, the bad, and the ugly of design History of 3D printing - Overview of 3D Printing technologies
Workflows for printing SLO-2
S-2 SLO-1 Duplication and arrayed duplication - Grid
and point/vertex snapping Moving Parts and Articulation Hinges - Ball and sockets
Prominent Designers Selective Laser Sintering (SLS) Direct Metal Laser Sintering (DMLS)
Software and Drivers - Formats for Printing (SLA, OBJ, CAD, etc.) SLO-2
S 3-4
SLO-1 Understanding NURBS: NURBS Surfaces advantages, Similarities and differences between NURBS and CAD drawings Curve and surface construction
Creating a part negative, Creating Text in Maya the proper way (NURBS Curves, surface lofts, conversion to polygon) Painterly tools (Sculpt Geometry Tool, etc.)
Franchises Success stories, Pop culture Vacuum forming - Resin casting - Injection Molding - Terms and standards for injection molding systems
Post and Export Print Lab setup SLO-2
S-5 SLO-1 Understanding 3D geometry - Modeling
workflows for Polygons - Additive vs. Subtractive Tools - Mesh editing
Flexibility and elasticity, Locks, bolts, and fasteners Threading (taps and dies)
Early decision making criteria Fused Deposition Modeling (FDM) -Stereolithography (SLA)
Cleanup and airtight modeling SLO-2
S-6
SLO-1 Best Practices for constructing printable polygon meshes
Interfacing, support, and reinforcement Knowing the product Laminated Object Manufacturing (LOM) - Electron Beam Melting (EBM)
Loading models and arranging print stage SLO-2
Fundamental Structure - Combining, merging, and sewing up polygon meshes
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 87
S 7-8
SLO-1 Best Practices for constructing printable polygon meshes - Fundamental Structure - Combining, merging, and sewing up polygon meshes
How the modeling software packages differ from CAD packages, Sketch/drawing based workflows, Similarities and differences between CAD and NURBS.
Brainstorming and critique in the early design phase Group critiques of in-progress projects
Printing Resolutions and Tolerances Materials Properties (Temperature, Flexibility, Strength, Brittleness)
Printing - Removing support material SLO-2
S-9 SLO-1
Understanding two-manifold vs. non-manifold geometry Form and function visualizing the assembly
process Early decision-making criteria Knowing the product Vision and Reality
3D Printing (3DP) – Selective laser melting (SLM)
Special topics – 3D Scanners and its types SLO-2
Exporting geometry - Laying out a simple model on a stage for print
S-10
SLO-1 Hollow forms and the importance of reducing volume Cost of size, cost of volume, cost of detail, cost of time State table
Complex interactions and motorizations Calculating the total cost Progress checks and group critiques of in-progress projects
Final cleanup and processing of files for printing
Reverse engineering, Concepts and its hardware and software SLO-2
S 11-12
SLO-1 Clean and uniform topology, Illustrator, IGES, and other import/export pipelines
Broad overview of manufacturing techniques Molding, sculpting, lathing, lofting, welding, cutting, drilling, gluing, etc
Brainstorming and critique in the early design phase Group critiques of in-progress projects
Planning for injection molding - 3D Printing for injection molding
High speed machining SLO-2
Learning Resources
1. Hod Lipson, Melba Kurman, Fabricated: The New World of 3D Printing, Wiley, 2013 2. Matthew Griffin, Design and Modeling for 3D Printing, Maker Media, Inc., 2013. 3. Rob Thompson, Manufacturing Processes for Design Professionals, Thames & Hudson; Reprint edition, 2007. 4. https://web.stanford.edu/class/me137/
5. SolidWorks Gallery: http://www.3dcontentcentral.com/default.aspx
6. 3D Anatomy Models: http://lifesciencedb.jp/bp3d/?lng=en 7. AutoDesk Fusion360 HomePage: http://fusion360.autodesk.com 8. International Journal of Rapid Manufacturing 9. Academic Journals on 3D Printing 10. International Journal of Rapid Manufacturing
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)#
Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
20% 20% 15% 15% 15% 15% 15% 15% 15% 15% Understand
Level 2 Apply
20% 20% 20% 20% 20% 20% 20% 20% 20% 20% Analyze
Level 3 Evaluate
10% 10% 15% 15% 15% 15% 15% 15% 15% 15% Create
Total 100 % 100 % 100 % 100 % -
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers
Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Mr. Anuj Kumar, Bombardier Transportation, Ahmedabad, [email protected] 1. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] 1. Mr. S. Karuppudaiyan, Mechanical, SRMIST
2. Mr. Hariharasudhan - Johnson Controls, Pune, [email protected] 2. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected] 2. Dr. P. Eswaran, SRMIST
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 88
Course Code
18ECO121T Course Name
BASIC BIOMEDICAL ENGINEERING Course
Category O Open Elective
L T P C
3 0 0 3
Pre-requisite Courses
Nil Co-requisite
Courses Nil
Progressive Courses
Nil
Course Offering Department Electronics and Communication Engineering with specialization in Biomedical Engineering
Data Book / Codes/Standards Nil
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Analyze the scopes and roles of Biomedical Engineering 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
CLR-2 : Utilize biomedical instrumentation modules
Leve
l of T
hink
ing
(Blo
om)
Exp
ecte
d P
rofic
ienc
y (%
)
Exp
ecte
d A
ttain
men
t (%
)
Eng
inee
ring
Kno
wle
dge
Pro
blem
Ana
lysi
s
Des
ign
& D
evel
opm
ent
Ana
lysi
s, D
esig
n, R
esea
rch
Mod
ern
Too
l Usa
ge
Soc
iety
& C
ultu
re
Env
ironm
ent &
Sus
tain
abili
ty
Eth
ics
Indi
vidu
al &
Tea
m W
ork
Com
mun
icat
ion
Pro
ject
Mgt
. & F
inan
ce
Life
Lon
g Le
arni
ng
PS
O-1
: Pro
blem
Sol
ving
at t
he
inte
rfac
e of
Eng
g. &
Med
icin
e P
SO
-:2:
Des
ign
& D
evel
op
Med
ical
Dev
ices
P
SO
-3: m
ultid
isci
plin
ary
rese
arch
for
heal
th c
are
solu
.
CLR-3 : Utilize medical imaging principles and its applications CLR-4 : Analyze the scope of biomechanics and its applications
CLR-5 : Utilize biomaterials and its applications
CLR-6 : Gain the knowledge about Biomedical Engineering
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Analyze the areas in which biomedical engineers can work 2 85 75 - - - - - - - - - - - L - - L CLO-2 : Analyze the basic biomedical instrumentation unit 3 85 75 L - - - - - - - - - - - - - L
CLO-3 : Analyze basic medical imaging principles 3 85 75 M - - - - - - - - - - - - - -
CLO-4 : Apply the concepts of biomechanics on human body 3 85 75 L - - - - - - - - - - - - - L
CLO-5 : Identify domains where biomedical engineers can work 3 85 75 - - - - - - - - - - - - - - -
CLO-6 : Analyze the applications of Biomedical Engineer 3 85 75 M - - - - - - - - - - L - - L
Duration (hour)
Introduction to Biomedical Engineering Biomedical Instrumentation Medical Imaging system Biomechanics Biomaterials
9 9 9 9 9
S-1 SLO-1
Evolution of the modern health care system
Introduction: Bioinstrumentation X-Ray production Introduction: Principal Areas of Biomechanics
Biomaterials Introduction
SLO-2 Modern Healthcare system Basic Bioinstrumentation System X-Ray Imaging principle Fundamentals of biomechanics and qualitative analysis
Classification of Biomaterials
S-2 SLO-1 What is Biomedical Engineering Physiological Systems of the body Application of X-ray imaging Kinematics of Human Body Models Properties of Biomaterials: Mechanical
SLO-2 Roles played by the Biomedical Engineers Sources of Biomedical Signals
CT-Imaging principle Kinetics of Human Body Models Properties of Biomaterials: Chemical
S-3 SLO-1 Types of Biomedical Engineering Origin of Bioelectric Signals CT-Imaging Applications Modelling of Bio systems Properties of Biomaterials: Biological
SLO-2 Surgical instruments and medical devices Origin of Bioelectric Signals MRI- Introduction
Tissue Biomechanics Biomedical alloys and its medical applications- titanium
S-4 SLO-1 Biomaterials
Various Electrodes used for picking the biomedical signals
MRI Imaging principles Modelling in Cellular Biomechanics Biomedical alloys and its applications- Stainless steel, Cobalt-Chromium alloys
SLO-2 Biomechanics Various Electrodes used for picking the biomedical signals
MRI Imaging principles Fluid mechanics Introduction to ceramics
S-5 SLO-1
Tissue Engineering
ECG Introduction MRI Imaging Applications Mechanics of the musculoskeletal system impact
Alumina, Zirconia
SLO-2 Neural Engineering ECG system Block diagram and its uses Ultrasound basics Mechanics of Blood Vessels Titanium, Hydroxyapatite
S-6 SLO-1 Telehealth EEG Introduction Ultrasound Imaging Cardiac Biomechanics Glass ceramics
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 89
SLO-2 Bio signal processing EEG system Block diagram and its uses Ultrasound Application Biomechanics of Chest and Abdomen Introduction to polymers
S-7 SLO-1 Medical Imaging EMG Introduction fMRI Imaging Cochlear Mechanics Types of polymers
SLO-2 Computational modelling EMG system Block diagram and its uses fMRI Imaging Application Dynamics of Human Body Models Biodegradable polymers and its applications
S-8 SLO-1 BioMEMS Cardiac pacemakers and its uses PET- Imaging Gait analysis Composites and its applications
SLO-2 Mobile POCT Cardiac Defibrillators and its uses PET Imaging Application Biomechanics in physical education Wound-Healing process
S-9 SLO-1
Professional Status of Biomedical Engineering
Patient Monitoring System Introduction SPECT Imaging Biomechanics in strength and conditioning Biomaterials for artificial valve, Ear
SLO-2 Professional Societies Patient Monitoring System Block diagram and its uses
SPECT Imaging Application
Biomechanics in sports medicine and rehabilitation
Biomaterials for artificial Skin, Eye
Learning Resources
1. Anthony Y. K. Chan, Biomedical Device Technology: Principles and Design, Charles C Thomas publisher, 2008
2. R.S Khandpur, Handbook of Biomedical Instrumentation, 3rd ed., McGraw Hill, 2014 3. Joseph J. Carr, John M.Brown, Introduction to Biomedical Equipment Technology, 4th ed., Pearson, 2002
4. John Enderle, Joseph Bronzino, Introduction to Biomedical Engineering, Academic Press, 2011 5. Andrew R Webb, Introduction to Biomedical Imaging, Wiley-IEEE Press, 2003 6. Sujata V. Bhat, Biomaterials, 2nd ed., Alpha Science International, 2005
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)#
Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
40 % - 30 % - 30 % - 30 % - 30% - Understand
Level 2 Apply
40 % - 40 % - 40 % - 40 % - 40% - Analyze
Level 3 Evaluate
20 % - 30 % - 30 % - 30 % - 30% - Create
Total 100 % 100 % 100 % 100 % 100 %
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers
Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Sathyanarayanan J, Mindray Medical India Pvt Ltd, [email protected] 1. Dr. S. Poonguzhali, Anna University, [email protected] 1. Ms. Oinam Robita Chanu, SRMIST
2. Mr. Anuj Kumar, Bombardier Transportation, Ahmedabad, [email protected] 2. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] 2. Dr. D. Kathirvelu, SRMIST
3. Mr. Hariharasudhan - Johnson Controls, Pune, [email protected] 3. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected]
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 90
Course Code
18ECO122T Course Name
HOSPITAL INFORMATION SYSTEMS Course
Category O Open Elective
L T P C
3 0 0 3
Pre-requisite Courses
Nil Co-requisite
Courses Nil
Progressive Courses
Nil
Course Offering Department Electronics and Communication Engineering with specialization in Biomedical Engineering
Data Book / Codes/Standards Nil
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Utilize the planning and organizational activities of Hospitals 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
CLR-2 : Analyze the concepts in clinical and diagnostic services
Leve
l of T
hink
ing
(Blo
om)
Exp
ecte
d P
rofic
ienc
y (%
)
Exp
ecte
d A
ttain
men
t (%
)
Eng
inee
ring
Kno
wle
dge
Pro
blem
Ana
lysi
s
Des
ign
& D
evel
opm
ent
Ana
lysi
s, D
esig
n, R
esea
rch
Mod
ern
Too
l Usa
ge
Soc
iety
& C
ultu
re
Env
ironm
ent &
Sus
tain
abili
ty
Eth
ics
Indi
vidu
al &
Tea
m W
ork
Com
mun
icat
ion
Pro
ject
Mgt
. & F
inan
ce
Life
Lon
g Le
arni
ng
PS
O-1
: Pro
blem
Sol
ving
at t
he
inte
rfac
e of
Eng
g. &
Med
icin
e P
SO
-:2:
Des
ign
& D
evel
op
Med
ical
Dev
ices
P
SO
-3: m
ultid
isci
plin
ary
rese
arch
for
heal
th c
are
solu
.
CLR-3 : Utilize the policies and procedures about support services and material management
CLR-4 : Utilize the features in staff and safety management in hospital CLR-5 : Analyze the reporting system and recent advancement in hospital administration
CLR-6 : Apply all the advanced application the field of telemedicine
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Analyze the role of hospitals and ensure proper healthcare delivery 2 85 75 L - - - - M - - - - - - L - - CLO-2 : Suggest appropriate technologies and services in clinical and diagnostic field 3 85 75 M - - - - - - - - - - - L - -
CLO-3 : Analyze the supportive services and the use of proper material management 3 85 75 M - - - - - M L - - - - M - L
CLO-4 : Identify objectives of staff management and ensure safety management in hospitals 3 85 75 M - - - - - - L - - - L L - -
CLO-5 : Implement the advance technologies and effectively evaluate the healthcare information 3 85 75 L - - - - M - L L - - - L L L
CLO-6 : Implement the various standards in hospital and healthcare services 3 85 75 L - - - - M - - - - - - L - -
Duration (hour)
Planning and designing of hospitals Inpatient and Outpatient services Material management services Management services in hospitals Patient record and advancement in
healthcare services
9 9 9 9 9
S-1 SLO-1 Hospital as a social system
Design and planning of emergency department
Pharmacy services- goals of hospital pharmacy services
Human resource management- Human resource development
Medical record management- Importance of medical record
SLO-2 Primary health care and hospitals Health information and counselling Staff organization and divisions of hospital pharmacy services
Hospital staff skill development Methods of record keeping
S-2 SLO-1
Hospital planning and design-Guiding principles in planning
Outpatient services –Types and functions of outpatient department
Benefits of formulatory system Nursing management-Functions of nursing management
Electronic medical record-Benefits and drawbacks
SLO-2 Regionalization of Hospital service
Physical features of outpatient department Other services of hospital pharmacy Nursing management- organizational structure
Record retention and disposal
S-3 SLO-1
Role of health promotion approach in hospitals
Ward/Indoor services-Components of the ward system
Transport services-Types of ambulance Biomedical waste management- Types and Composition of Biomedical Waste
Office management -skills required by the office staff
SLO-2 Health promoting hospital system Design of special units Communication and physical facilities of ambulance service
Categories of biomedical waste Functions of office management
S-4 SLO-1 Healthy hospital environment
Operation theatre services-Planning and designing of Operation theatres
Staff transport services Concept of total quality management
Operations research in hospitals-Phases of operation research
SLO-2 Components of healthy hospital environment
Types of Operation theatres Other transport services in hospitals Types of approaches in quality
management Operations research in hospitals- Tools and techniques of operations research
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 91
S-5 SLO-1 Creating manpower services
Policies and procedures of operation theatres
Medicolegal services- Steps for Medicolegal Examination
Quality assessment and management tools
Emerging health insurance – components of health insurance
SLO-2 Hospital engineering: Key to efficient healthcare services
Assessing operation theatre utilisation Problems faced by healthcare professionals in medicolegal service
Clinical audit Emerging health insurance-Types of health insurance
S-6 SLO-1
Designing disabled friendly hospitals- Barriers faced and implications in Persons with disabilities
Clinical laboratory services-Introduction and role of laboratory medicine
Food safety in hospitals-Need of food safety
Quality improvement-Cause and effect method
Advantages and common problems of health insurance schemes
SLO-2 Need for disabled-friendly health services Testing procedure in clinical laboratory Sources of food contamination Pareto analysis Role of health and hospital administrators in Health insurance
S-7 SLO-1
Barrier-Free Environment to Universal Design
Radio diagnosis and imaging services-Planning and equipments of radiology department
Materials management- Principles of material management
Failure mode and effect analysis Telemedicine clinic –functions and classification of telemedicine
SLO-2 Overcoming the barriers Advancement in radiology service Concepts of Inventory control Triggers of quality improvement strategy in a hospital
Challenges for telemedicine
S-8 SLO-1 Energy conservation- Classification
Radiation oncology service-Radiotherapy facilities
Modern techniques for inventory control Occupational safety-Roles and responsibilities
Growth of mobile phones and potential of mobile health
SLO-2 Types of energy streams in hospitals Nuclear medicine services-Categorization and nuclear medicine department
Integrated concept for materials management
Prevention of hazards specific to health sector
Mobile health and its applications
S-9 SLO-1 Need for energy conservation Planning of nuclear medicine department
Purchase and procurement system-Essentials for procurement process
Hospital security-Physical security Challenges in implementing information and Communication technology in healthcare
SLO-2 Energy conservation opportunities in hospitals
Ancillary requirements Purchase system Organizational chart of security wing
Information and communication technology applications in healthcare
Learning Resources
1. SonuGoel, Anil Kumar Gupta, Amarjeet Singh, Hospital administration A problem- solving approach, 1st ed., Elsevier, 2014
2. Sakharkar B M, Principles of hospital administration and planning, 2nd ed., Jaypee Brothers Medical Publishers, 2009 3. Kunders G D, Hospitals: Facilities planning and management, 1st ed., Tata Mcgraw Hill, 2008
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)#
Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
40 % - 30 % - 30 % - 30 % - 30% - Understand
Level 2 Apply
40 % - 40 % - 40 % - 40 % - 40% - Analyze
Level 3 Evaluate
20 % - 30 % - 30 % - 30 % - 30% - Create
Total 100 % 100 % 100 % 100 % 100 %
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers
Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Sathyanarayanan J, Mindray Medical India Pvt Ltd, [email protected] 1. Dr. S. Poonguzhali, Anna University, [email protected] 1. Dr. D. Ashokkumar, SRMIST
2. Mr. Anuj Kumar, Bombardier Transportation, Ahmedabad, [email protected] 2. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] 2. Mr. P. Muthu, SRMIST
3. Mr. Hariharasudhan - Johnson Controls, Pune, [email protected] 3. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected]
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 92
Course Code
18ECO123T Course Name
BIOMEDICAL IMAGING Course
Category O Open Elective
L T P C
3 0 0 3
Pre-requisite Courses
Nil Co-requisite
Courses Nil
Progressive Courses
Nil
Course Offering Department Electronics and Communication Engineering with specialization in Biomedical Engineering
Data Book / Codes/Standards Nil
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Utilize the working principle of X-ray imaging 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
CLR-2 : Analyze the principle behind tomographic imaging and the reconstruction techniques
Leve
l of T
hink
ing
(Blo
om)
Exp
ecte
d P
rofic
ienc
y (%
)
Exp
ecte
d A
ttain
men
t (%
)
Eng
inee
ring
Kno
wle
dge
Pro
blem
Ana
lysi
s
Des
ign
& D
evel
opm
ent
Ana
lysi
s, D
esig
n, R
esea
rch
Mod
ern
Too
l Usa
ge
Soc
iety
& C
ultu
re
Env
ironm
ent &
Sus
tain
abili
ty
Eth
ics
Indi
vidu
al &
Tea
m W
ork
Com
mun
icat
ion
Pro
ject
Mgt
. & F
inan
ce
Life
Lon
g Le
arni
ng
PS
O-1
: Pro
blem
Sol
ving
at t
he
inte
rfac
e of
Eng
g. &
Med
icin
e P
SO
-:2:
Des
ign
& D
evel
op
Med
ical
Dev
ices
P
SO
-3: m
ultid
isci
plin
ary
rese
arch
for
heal
th c
are
solu
.
CLR-3 : Interpret the theory behind nuclear medicine and utilize the working of imaging modalities in nuclear medicine
CLR-4 : Analyze the physics of ultrasound and the different imaging modes using ultrasound
CLR-5 : Utilize the physical principle of nuclear magnetic resonance and magnetic resonance image reconstruction
CLR-6 : The learner will be to gain knowledge in the working principle of imaging modalities using X-ray, computed tomography, nuclear medicine, ultrasound and magnetic resonance imaging.
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Analyze the physics and principle behind the working of X-ray imaging 2 85 75 M - - - - - - - - - - - M - - CLO-2 : Identify the principle behind working of tomographic imaging and reconstruction procedures. 3 85 75 M - - - - - - - - - - - M - -
CLO-3 : Analyze the working principle of nuclear medicine imaging modalities 3 85 75 M - - - - - - - - - - - M - -
CLO-4 : Identify the physics of ultrasound and the modes of ultrasound imaging 3 85 75 M - - - - - - - - - - - M - -
CLO-5 : Explain the physical principle of magnetic resonance imaging and the instrumental components involved in MR imaging 3 85 75 M - - - - - - - - - - - M - -
CLO-6 : Understand the basic principle and working of medical Imaging systems 3 85 75 M - - - - - - - - - - - M - -
Duration (hour)
X-ray Computed Tomography Ultrasound Magnetic Resonance Imaging Nuclear medicine
9 9 9 9 9
S-1 SLO-1 General principles of Imaging with X-rays Introduction: Tomographic Imaging
Characteristics of sound: Propagation, wavelength, frequency and speed
Principles of NMR Imaging Radionuclide decay terms and relationship
SLO-2 X-ray Production –X-ray source Comparison between tomographic and planar imaging
Pressure, Intensity and dB scale Free Induction decay Nuclear transformation
S-2 SLO-1 X-ray tube current, tube output
Basic principle: Technique of producing CT images
Interaction of ultrasound with matter: Acoustic impedance, reflection, refraction
Excitation, Emission Radionuclide production
SLO-2 Beam intensity, X-ray Energy Spectrum Contrast scale Scattering, Attenuation Relaxation times-T1 & T2 Radiopharmaceuticals
S-3 SLO-1 Coherent and Compton scattering
System components: first generation, second generation, third generation,
Transducers: Piezoelectric materials, resonance transducers
Spin echo technique Radiation detection and measurement: types of detectors, Gas-filled detectors
SLO-2 Photoelectric effect Fourth, fifth and spiral/helical CT Damping block, matching layer, Resolution Spin echo contrast weighting Scintillation detectors
S-4 SLO-1
Linear and Mass attenuation coefficient of X-rays in tissue
X-ray source, types of detectors Transducer arrays T1 weighted image Semiconductor detectors
SLO-2 Instrumentation for Planar X-ray Imaging: Collimators
Gantry and slip ring technology, Collimation and filtration
Multi-element linear array scanners T2 weighted image Pulse height spectroscopy
S-5 SLO-1 Antiscatter grids Intensifying screens Processing system Multi-linear and phased array Gradient recalled sequence Non-imaging detector applications
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 93
SLO-2 X-ray films Iterative reconstruction, back projection reconstruction
Generation and detection of ultrasound Proton density weighted images, pulse sequence for fast imaging
Counting statistics
S-6 SLO-1
Instrumentation for computed and digital radiography
Filtered back projection Basic pulse echo apparatus: A-scan Slice selection gradient Nuclear imaging
SLO-2 X-ray Image characteristics: Signal to Noise ratio Helical /Spiral CT: Helical pitch B-Mode Frequency encode gradient Anger scintillation camera
S-7 SLO-1 Spatial resolution, Contrast to Noise ratio Basic reconstruction approaches M-mode Phase encode gradient
Basic principle :Emission computed tomography
SLO-2 X-ray contrast agents, X-ray angiography Slice sensitivity profile Echocardiograph 2D spin echo data acquisition Single photon emission computed tomography
S-8 SLO-1 X-ray Fluoroscopy Multislice CT Duplex scanner
Basic NMR components: Main magnet, RF transmitter/receiver
Positron emission tomography
SLO-2 X-ray mammography Detector configuration Intravascular imaging Body coils, gradient coils Imaging techniques and scanner instrumentation
S-9 SLO-1 Dual energy Imaging Measurement of X-ray dosage
Artefacts: Refraction, shadowing and enhancement
fMRI : Basic principle Dual modality: PET/CT
SLO-2 Abdominal X-ray scans Methods for dose reduction Reverberation BOLD concept, MR spectroscopy Working and applications
Learning Resources
1. R.S.Khandpur, Handbook of Biomedical instrumentation, 3rd ed., Tata McGraw Hill, 2014 2. Jerrold T. Bushberg, John M. Boone, The essential physics of medical imaging, 3rd ed., Lippincott Williams &
Wilkins, 2011
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)# Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
40 % - 30 % - 30 % - 30 % - 30% - Understand
Level 2 Apply
40 % - 40 % - 40 % - 40 % - 40% - Analyze
Level 3 Evaluate
20 % - 30 % - 30 % - 30 % - 30% - Create
Total 100 % 100 % 100 % 100 % 100 %
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers
Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Sathyanarayanan J, Mindray Medical India Pvt Ltd, [email protected] 1. Dr. S. Poonguzhali, Anna University, [email protected] 1. Dr. T. Jayanthi, SRMIST
2. Mr. Anuj Kumar, Bombardier Transportation, Ahmedabad, [email protected] 2. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] 2. Dr. U. Snekhalatha, SRMIST
3. Mr. Hariharasudhan - Johnson Controls, Pune, [email protected] 3. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected]
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 94
Course Code
18ECO124T Course Name
HUMAN ASSIST DEVICES Course
Category O Open Elective
L T P C
3 0 0 3
Pre-requisite Courses
Nil Co-requisite
Courses Nil
Progressive Courses
Nil
Course Offering Department Electronics and Communication Engineering with specialization in Biomedical Engineering
Data Book / Codes/Standards Nil
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Utilize the latest technology and device used for assisting human disability 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
CLR-2 : Analyze various devices used for mobility
Leve
l of T
hink
ing
(Blo
om)
Exp
ecte
d P
rofic
ienc
y (%
)
Exp
ecte
d A
ttain
men
t (%
)
Eng
inee
ring
Kno
wle
dge
Pro
blem
Ana
lysi
s
Des
ign
& D
evel
opm
ent
Ana
lysi
s, D
esig
n, R
esea
rch
Mod
ern
Too
l Usa
ge
Soc
iety
& C
ultu
re
Env
ironm
ent &
Sus
tain
abili
ty
Eth
ics
Indi
vidu
al &
Tea
m W
ork
Com
mun
icat
ion
Pro
ject
Mgt
. & F
inan
ce
Life
Lon
g Le
arni
ng
PS
O-1
: Pro
blem
Sol
ving
at t
he
inte
rfac
e of
Eng
g. &
Med
icin
e P
SO
-:2:
Des
ign
& D
evel
op
Med
ical
Dev
ices
P
SO
-3: m
ultid
isci
plin
ary
rese
arch
for
heal
th c
are
solu
.
CLR-3 : Utilize the various assist device used for hearing
CLR-4 : Utilize the various assist device used for vision CLR-5 : Utilize the various assist device used in orthopaedic
CLR-6 : Analyze the working principles of cardiac assist devices and Artificial kidney
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Comprehend the assistive technology (AT) used for mobility 2 85 75 M - - - - - - - - - - - M - - CLO-2 : Analyze the Assist technology used for hearing 3 85 75 M - - - - - - - - - - - - L -
CLO-3 : Evaluate the Assist technology used for sensory impairment of vision 3 85 75 - - - - - - - - - - - - - L -
CLO-4 : Evaluate the assist device used in orthopedic 3 85 75 M - - - - - - - - - - - M L -
CLO-5 : Analyze the latest use of assist technology in health care 3 85 75 M - - - - - - - - - - - M - -
CLO-6 : Design the prosthetic heart valves and pacemaker 3 85 75 M - - - - - - - - - - - M - -
Duration (hour)
9 9 9 9 9
S-1 SLO-1
Basic assessment and evaluation for mobility
Basic ear anatomy, Mechanism of hearing Anatomy of eye Anatomy of upper & lower extremities - Basic Anatomy and physiology of heart.
SLO-2 Basic assessment and evaluation for mobility
Common tests audiograms Categories of visual impairment Classification of amputation types Cardiac assist devices
S-2 SLO-1 Manual wheelchairs Air conduction, Bone conduction
Intraocular Devices
Prosthesis prescription Intra-Aortic Balloon Pump (IABP),
SLO-2 Electric power wheelchairs Masking techniques, Extraocular Devices Hand and arm replacement Prosthetic heart valves
S-3 SLO-1 Power assisted wheelchairs SISI Permanent Vision Restoration
Different types of models, externally powered limb prosthesis
Evaluation of prosthetic valve
SLO-2 Wheel chair standards & tests - Hearing aids principles Non-Permanent Vision Restoration Different types of models, externally powered limb prosthesis
Heart pacemaker
S-4 SLO-1 Wheel chair transportation Drawbacks in the conventional unit Voice Control Sound Control. Foot orthosis CABG
SLO-2 Control systems, navigation in virtual space by wheelchairs
DSP based hearing aids Sensor Technology Adapted for the Vision Impaired
Pediatric orthoses Extracorporeal support
S-5 SLO-1 Wheel chair seating and pressure ulcers. Cochlear Implants Libraille Wrist-hand orthosis Vascular prosthesis
SLO-2 EOG based voice controlled wheelchair Internal Hearing Aid GRAB feedback in orthotic system Vascular prosthesis
S-6 SLO-1 BCI based wheelchair External Hearing Aid mathematical Braille Components of upper limb prosthesis Artificial heart
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 95
SLO-2 Fuzzy logic expert system for automatic tuning of myoelectric prostheses
Permanent Hearing Restoration Blind mobility aids Components of lower limb prosthesis Intermittent positive pressure breathing (IPPB) type assistance for lungs
S-7 SLO-1 Intelligent prosthesis Non-Permanent Hearing Restoration Reading writing & graphics access,
Lower extremity- and upper extremity- orthoses
Dialysis for kidneys
SLO-2 Intelligent prosthesis Touch Tactile Haptic Technology Orientation & navigation Aids Lower extremity- and upper extremity- orthoses
Artificial Kidney
S-8 SLO-1 Future trends in assistive technology Sound Coding Translation Wearable Assistive Devices for the Blind functional electrical stimulation Haemodialysis
SLO-2 virtual reality based training system for disabled children
Acoustic Transducers Hearing Quality Wearable tactile display for the fingertip. Sensory assist devices Membrane dialysis
S-9 SLO-1
Information technology, telecommunications,
Electric Electronic Stimulation Cortical implants Sensory assist devices Portable dialysis monitoring and functional parameter
SLO-2 new media in assisting healthcare Hearing Enhancement Retinal implants Slints – materials used Latest use of assistive technology for chronic heart diseases and healthcare
Learning Resources
1. Levine S.N. Advances in Bio-medical engineering and Medical physics, 1st ed., Vol. I, II, IV, Interuniversity publications, 1968.
2. Marion. A. Hersh, Michael A. Johnson, Assistive Technology for visually impaired and blind, 1st ed., Springer Science & Business Media, 2010
3. Kopff W.J, Artificial Organs, 1st ed., John Wiley and Sons, 1976 4. Daniel Goldstein, Mehmet Oz, Cardiac assist Devices, Wiley, 2000 5. Kenneth J. Turner, Advances in Home Care Technologies: Results of the match Project, 1st ed., Springer, 2011
6. Albert M.Cook, Webster J.G, Therapeutic Medical Devices, Prentice Hall Inc.,1982 7. Gerr .M. Craddock Assistive Technology-Shaping the future, 1st ed., IOS Press, 2003 8. Brownsell, Simon, et al,. A systematic review of lifestyle monitoring technologies, Journal of
telemedicine and telecare 17.4 (2011): 185-189 9. Yadin David, Wolf W. von Maltzahn, Michael R. Neuman, Joseph.D, Bronzino, Clinical
Engineering, 1st ed., CRC Press, 2010 10. Pascal Verdonck, Advances in Biomedical Engineering, 1st ed., Elsevier, 2009
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)#
Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
40 % - 30 % - 30 % - 30 % - 30% - Understand
Level 2 Apply
40 % - 40 % - 40 % - 40 % - 40% - Analyze
Level 3 Evaluate
20 % - 30 % - 30 % - 30 % - 30% - Create
Total 100 % 100 % 100 % 100 % 100 %
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers
Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Sathyanarayanan J, Mindray Medical India Pvt Ltd, [email protected] 1. Dr. S. Poonguzhali, Anna University, [email protected] 1. Mrs. Lakshmi Prabha, SRMIST
2. Mr. Anuj Kumar, Bombardier Transportation, Ahmedabad, [email protected] 2. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] 2. Dr. U. Snekhalatha, SRMIST
3. Mr. Hariharasudhan - Johnson Controls, Pune, [email protected] 3. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected]
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 96
Course Code
18ECO125T Course Name
QUALITY CONTROL FOR BIOMEDICAL DEVICES Course
Category O Open Elective
L T P C
3 0 0 3
Pre-requisite Courses
Nil Co-requisite
Courses Nil
Progressive Courses
Nil
Course Offering Department Electronics and Communication Engineering with specialization in Biomedical Engineering
Data Book / Codes/Standards Nil
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Utilize Quality, Quality control measures essential for an organization 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
CLR-2 : Utilize the quality management principles and good management practices
Leve
l of T
hink
ing
(Blo
om)
Exp
ecte
d P
rofic
ienc
y (%
)
Exp
ecte
d A
ttain
men
t (%
)
Eng
inee
ring
Kno
wle
dge
Pro
blem
Ana
lysi
s
Des
ign
& D
evel
opm
ent
Ana
lysi
s, D
esig
n, R
esea
rch
Mod
ern
Too
l Usa
ge
Soc
iety
& C
ultu
re
Env
ironm
ent &
Sus
tain
abili
ty
Eth
ics
Indi
vidu
al &
Tea
m W
ork
Com
mun
icat
ion
Pro
ject
Mgt
. & F
inan
ce
Life
Lon
g Le
arni
ng
PS
O-1
: Pro
blem
Sol
ving
at t
he
inte
rfac
e of
Eng
g. &
Med
icin
e P
SO
-:2:
Des
ign
& D
evel
op
Med
ical
Dev
ices
P
SO
-3: m
ultid
isci
plin
ary
rese
arch
for
heal
th c
are
solu
.
CLR-3 : Utilize the various quality control tools
CLR-4 : Utilize the various quality management tools
CLR-5 : Analyze the various standards applicable to healthcare globally and nationally CLR-6 : Implement the global standards in healthcare
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Analyze the underlying concepts of quality and quality control concepts of an organization 2 85 75 - - - - - - - - - - - L - - L
CLO-2 : Evaluate the various quality management principles and good management practices 3 85 75 L - - - - - - - - - - - - - L CLO-3 : Evaluate various tools of quality control 3 85 75 M - - - - - - - - - - - - - -
CLO-4 : Analyze the various quality management tools 3 85 75 L - - - - - - - - - - - - - L
CLO-5 : Analyze the various standards applicable to healthcare globally and nationally 3 85 75 - - - - - - - - - - - - - - -
CLO-6 : Analyze the outcomes of implementing global standards 3 85 75 M - - - - - - - - - - L - - L
Duration (hour)
Introduction to quality TQM principles Statistical process control TQM tools Quality systems
9 9 9 9 9
S-1 SLO-1 Definition of Quality
Customer satisfaction – Customer Perception of Quality
The seven tools of quality Benchmarking ISO 9000 Systems
SLO-2 Dimensions of Quality Customer Complaints Cause-and-effect diagram Reasons to Benchmark ISO 9000 Systems
S-2 SLO-1 Quality Planning Service Quality Check sheet Benchmarking Process
ISO 9000:2000 Quality System – Elements
SLO-2 Quality Planning Customer Retention Check sheet Benchmarking Process ISO 9000:2000 Quality System – Elements
S-3 SLO-1 Quality costs Employee Involvement Control chart Quality Function Deployment (QFD) Need for Accreditation of hospitals
SLO-2 Quality costs Motivation Control chart Quality Function Deployment (QFD) Need for Accreditation of hospitals
S-4 SLO-1
Basic concepts of Total Quality Management
Empowerment Histogram House of Quality FDA Regulations
SLO-2 Principles of TQM Teams and Team Work Histogram House of Quality FDA Regulations
S-5 SLO-1 Leadership – Concepts Recognition and Reward Pareto chart QFD Process - Benefits Joint Commission
SLO-2 Role of Senior Management Performance Appraisal Pareto chart QFD Process - Benefits Joint Commission
S-6 SLO-1 Quality Council Juran Trilogy Scatter diagram Total Productive Maintenance (TPM) – Concept
Regulatory Bodies of India
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 97
SLO-2 Quality Statements Juran Trilogy Scatter diagram Total Productive Maintenance Medical Council of India
S-7 SLO-1 Strategic Planning PDSA Cycle Stratification Improvement Needs Pharmacy Council Of India
SLO-2 Strategic Planning PDSA Cycle Stratification Improvement Needs Pharmacy Council Of India
S-8 SLO-1 Deming Philosophy Kaizen Six sigma FMEA Indian Nursing Council
SLO-2 Deming Philosophy Kaizen Six sigma FMEA Indian Nursing Council
S-9 SLO-1 Barriers to TQM Implementation 5S Six sigma Stages of FMEA Dental Council of India
SLO-2 Barriers to TQM Implementation 5S Six sigma Stages of FMEA Homeopathy Central Council
Learning Resources
1. Rose J.E, Total Quality Management, Kogan Page Ltd., 1993 2. Cesar A. Cacere, Albert Zana,The Practise of clinical Engineering, Academic Press,1997 3. Greg Bounds, Beyond Total Quality Management-Toward the emerging paradigm, McGraw
Hill, 2013
4. Joseph J.Carr, Elements of Electronics Instrumentation and Measurement, 2nd ed., Pearson Education, 2003 5. Jerrold T. Bushberg, John M. Boone, The essential physics of medical imaging, 3rd ed., Lippincott Williams &
Wilkins, 2011
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)#
Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
40 % - 30 % - 30 % - 30 % - 30% - Understand
Level 2 Apply
40 % - 40 % - 40 % - 40 % - 40% - Analyze
Level 3 Evaluate
20 % - 30 % - 30 % - 30 % - 30% - Create
Total 100 % 100 % 100 % 100 % 100 %
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers
Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Sathyanarayanan J, Mindray Medical India Pvt Ltd, [email protected] 1. Dr. S. Poonguzhali, Anna University, [email protected] 1. Dr. D. Kathirvelu, SRMIST
2. Mr. Anuj Kumar, Bombardier Transportation, Ahmedabad, [email protected] 2. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] 2. Dr. D. Ashok Kumar, SRMIST
3. Mr. Hariharasudhan - Johnson Controls, Pune, [email protected] 3. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected]
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 98
Course Code
18ECO126T Course Name
SPORTS BIOMECHANICS Course
Category E Professional Elective
L T P C
3 0 0 3
Pre-requisite Courses
18ECE267J Co-requisite
Courses Nil
Progressive Courses
Nil
Course Offering Department Electronics and Communication Engineering Data Book / Codes/Standards Nil
Course Learning Rationale (CLR): The purpose of learning this course is to:
Learning
Program Learning Outcomes (PLO)
CLR-1 : Understand the fundamental muscle action and locomotion in biomechanical point of view 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 CLR-2 : Get an idea about the movement patterns and causes of movements
Leve
l of T
hink
ing
(Blo
om)
Exp
ecte
d P
rofic
ienc
y (%
)
Exp
ecte
d A
ttain
men
t (%
)
Eng
inee
ring
Kno
wle
dge
Pro
blem
Ana
lysi
s
Des
ign
& D
evel
opm
ent
Ana
lysi
s, D
esig
n, R
esea
rch
Mod
ern
Too
l Usa
ge
Soc
iety
& C
ultu
re
Env
ironm
ent &
Sus
tain
abili
ty
Eth
ics
Indi
vidu
al &
Tea
m W
ork
Com
mun
icat
ion
Pro
ject
Mgt
. & F
inan
ce
Life
Lon
g Le
arni
ng
PS
O-1
: Pro
blem
Sol
ving
at t
he
inte
rfac
e of
Eng
g. &
Med
icin
e P
SO
-:2:
Des
ign
& D
evel
op
Med
ical
Dev
ices
P
SO
-3: m
ultid
isci
plin
ary
rese
arch
for
heal
th c
are
solu
.
CLR-3 : Understand the qualitative and quantitative analysis of sports movements
CLR-4 : Acquire an idea about the basic concept of jumping & aerial movement and throwing & hitting
CLR-5 : Get an idea about the injury prevention, rehabilitation and special Olympic sports
CLR-6 : Get an overall idea about the applications of biomechanics in sports
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Illustrate the muscle action in sport and locomotion 1 80 70 M L
CLO-2 : Analyze the movement patterns and its causes 1,2 80 70 M M
CLO-3 : Describe the Qualitative and Quantitative analysis of sports movements 2 80 70 M M CLO-4 : Analyze the movement of action such as jumping, throwing, hitting and aerial movement 2 80 70 L L L L
CLO-5 : Identify the injury scenario and special Olympic sports 2 80 70 L L L
CLO-6 : Outline the major concepts in sports biomechanics
Duration (hour)
Muscle Action in Sport and Exercise and locomotion- Biomechanical view
Movement patterns and its causes Qualitative and Quantitative analysis of sports movements
Jumping and Aerial Movement, Throwing and Hitting
Injury Prevention, Rehabilitation and Special Olympic Sports
9 9 9 9 9
S-1 SLO-1 Introduction to Biomechanics Introduction to Movement patterns
Introduction to Analysis of Sport Movements
Introduction to Aerial movement Mechanisms of Musculoskeletal Injury
SLO-2 Applications of Biomechanics Defining human movements A structured analysis framework Types of Aerial Movement - Rotation during flight, Motion of the mass centre
Musculoskeletal Loading During Landing
S-2
SLO-1 Neural Contributions to Changes in Muscle Strength
Fundamental movements-Walking, Running
Preparation stage Types of Aerial Movement : Somersaulting, Twisting,
Sport-Related Spinal Injuries and their Prevention
SLO-2 Mechanical Properties and Performance in Skeletal Muscles
Fundamental movements-Throwing, Jumping
Observation stage Control of aerial movement Sport-Related Spinal Injuries and their Prevention
S-3
SLO-1 Muscle-Tendon Architecture qualitative and quantitative movement Evaluation and diagnosis stage Introduction : High Jump Impact Propagation and its Effects on the Human Body
SLO-2 Athletic Performance Comparison of qualitative and quantitative movement analysis
Intervention stage – providing appropriate feedback
Techniques of Jumping -
Skating, Springboard and Platform Diving
Impact Propagation and its Effects on the Human Body
S-4 SLO-1
Eccentric Muscle Action in Sport and Exercise
Movement patterns-geometry of motion Identifying critical features of a movement Determinants of Successful Ski-Jumping Performance
Neuromechanics of the Initial Phase of Eccentric Contraction
SLO-2 Stretch–Shortening Cycle of Muscle Function
Fundamentals of movement Identifying critical features of a movement Determinants of Successful Ski-Jumping Performance
Induced Muscle Injury
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 99
S-5 SLO-1 Biomechanical Foundations of Strength Linear motion and the centre of mass
The use of videography in recording sports movements
Principles of Throwing Manual Wheelchair Propulsion
SLO-2 Power Training The geometry of angular motion and the coordination of joint rotations
The use of videography in recording sports movements
The Flight of Sports Projectiles
S-6 SLO-1
Factors Affecting Preferred Rates of Movement in Cyclic Activities
Forces in sport Recording the movement Javelin Throwing: an Approach to Performance Development
Sports after Amputation SLO-2 The Dynamics of Running
Combinations of forces on the sports performer
Experimental procedures -Two dimensional videography
S-7 SLO-1 Resistive Forces in Swimming Momentum and the laws of linear motion
Experimental procedures -Three dimensional videography
Shot Putting Biomechanics of Dance
SLO-2 Propulsive Forces in Swimming
Force–time graphs as movement patterns Data processing Hammer Throwing: Problems and Prospects
S-8
SLO-1 Performance-Determining Factors in Speed Skating
Determination of the centre of mass of the human body
Projectile motion Hammer Throwing: Problems and Prospects
Biomechanics of Martial arts SLO-2
Cross-Country Skiing: Technique
Fundamentals of angular kinetics and Generation and control of angular momentum
Linear velocities and accelerations caused by rotation
Hitting
S-9 SLO-1
Cross-Country Skiing: Equipment
Measurement of force Rotation in three-dimensional space Kicking Biomechancis of YOGA
SLO-2 Factors Affecting Performance Measurement of pressure Rotation in three-dimensional space Simple concept problems
Learning Resources
1. Susan J Hall, “Basic Biomechanics”, McGraw-Hill Higher Education, 7th edition, 2014 2. Vladimir M. Zatsiorsky, Biomechanics in Sports: Performance Enhancement and Injury
Prevention, 1st ed., Blackwell Science Ltd, 2000
3. Jules Mitchell,”Yoga Biomechanics”, 1 edition , Handspring Publishing Limited ,2018 4. Roger Bartlett, Introduction to Sports Biomechanics: Analysing Human Movement Patterns, 2nd ed., Routledge,
2007
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)#
Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
40 % - 40 % - 40 % - 30 % - 30% - Understand
Level 2 Apply
40 % - 40 % - 40 % - 40 % - 40% - Analyze
Level 3 Evaluate
20 % - 20 % - 20 % - 30 % - 30% - Create
Total 100 % 100 % 100 % 100 % 100 %
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers
Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. Sathyanarayanan J, Mindray Medical India Pvt Ltd, [email protected] 1. Dr. S. Poonguzhali, Anna University, [email protected] 1. Ms. Oinam Robita Chanu, SRMIST
2. Mr. Anuj Kumar, Bombardier Transportation, Ahmedabad, [email protected] 2. Dr. Meenakshi, Professor of ECE, CEG, Anna University, [email protected] 2. Dr .D. Ashok kumar, SRMIST
. Mr. Hariharasudhan - Johnson Controls, Pune, [email protected] 3. Dr. Venkatesan, Sr. Scientist, NIOT, Chennai, [email protected]
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 100
Course Code
18ECO131J Course Name
VIRTUAL INSTRUMENTATION Course
Category O Open Elective
L T P C
2 0 2 3
Pre-requisite Courses
Nil Co-requisite
Courses Nil
Progressive Courses
Nil
Course Offering Department Electronics and Communication Engineering Data Book / Codes/Standards Nil
Course Learning Rationale (CLR): The purpose of learning this course is to:
Learning
Program Learning Outcomes (PLO)
CLR-1 : Study the concepts of Virtual instrumentation and to learn the programming concepts in VI. 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
CLR-2 : Study about the various real time data acquisition methods.
Leve
l of T
hink
ing
(Blo
om)
Exp
ecte
d P
rofic
ienc
y (%
)
Exp
ecte
d A
ttain
men
t (%
)
Eng
inee
ring
Kno
wle
dge
Pro
blem
Ana
lysi
s
Des
ign
& D
evel
opm
ent
Ana
lysi
s, D
esig
n, R
esea
rch
Mod
ern
Too
l Usa
ge
Soc
iety
& C
ultu
re
Env
ironm
ent &
Sus
tain
abili
ty
Eth
ics
Indi
vidu
al &
Tea
m W
ork
Com
mun
icat
ion
Pro
ject
Mgt
. & F
inan
ce
Life
Lon
g Le
arni
ng
PS
O 1
: Aut
omat
ic c
ontr
ol f
or
cont
inou
s &
dis
cret
e sy
stem
s P
SO
-2: U
tiliz
e P
LC &
DC
S fo
r co
ntro
l of s
yste
ms
PS
O-3
: Effe
ctiv
e
man
agem
ent s
kills
CLR-3 : Study about the various Instrument Interfacing concepts.
CLR-4 : To study the programming techniques for various control techniques using VI software
CLR-5 : To study various analysis tools for Process control applications.
CLR-6 : To study various real time measurement systems
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : An ability to understand the purpose of virtual instrumentation and understand the construction of VI 1,2 80 70 H H
CLO-2 : An ability to understand and apply various data acquisition methods. 2 85 75 H H H
CLO-3 : An ability to understand and implement the available interfacing instruments 2 75 70 H H H H H H H H
CLO-4 : An ability to understand and implement various control techniques using VI software 2,3 85 80 H H H H H H H
CLO-5 : An ability to understand and develop a program foran engineering application. 2,3 85 75 H H H H H H H H H H H
CLO-6 : An ability to understand and implement various measurement systems 2,3 80 70 H H H H H H H H H H H
Duration (hour) Learning Unit / Module 1 Learning Unit / Module 2 Learning Unit / Module 3 Learning Unit / Module 4 Learning Unit / Module 5
12 12 12 12 12
S-1
SLO-1 Historical perspective, Need of VI, Advantages of VI, Virtual Instruments versus Traditional Instruments
A/D Converters, Organization of the DAQ VI system -
Introduction to PC Buses Introduction to Non continuous controllers in LabVIEW
PC based digital storage oscilloscope
SLO-2
Review of software in Virtual Instrumentation ,Software environment Architecture of VI, Introduction to the block diagram and Front panel Pallets
D/A Converters, Types of D/A
Local Buses-ISA, PCI, Introduction to continuous controllers in LabVIEW
Sensor Technology
S-2
SLO-1 Creating and saving a VI, Front Panel Tool Bar, Block diagram Tool Bar, Palettes
plug-in Analog Input/output cards - Digital Input and Output Cards,
RS232, RS422 Design of ON/OFF controller Applications of sensor Technology
SLO-2
Creating sub VI, Creating an ICON, Building a connector pane, Displaying VI’S, Placing and Saving Sub VI’S on block diagram, Example of full adder circuit using half adder circuit
Organization of the DAQ VI system - RS485 Proportional controller for a mathematically described processes using VI software
Signal processing Techniques
S-3 SLO-1 Lab-1: Front Panel controls and Indicator
Lab-12: Measurement of diode I-V characteristics using LabVIEW Lab-17: Load cell Data acquisition
using RS232
Lab-22: On-off temperature controller using LabVIEW
Lab-28: Design of DSO SLO-2
Lab-2: Verification of Arithmetic Operations
S-4 SLO-1 Lab-3: Verification of Half Adder Lab-13: Temperature measurement using
LabVIEW and DAQ hardware. Lab-23: Continuous Control of temperature using LabVIEW
Lab-29: Analysis of different signal Filters using LabVIEW SLO-2 Lab-4: Verification of Full adder.
S-5 SLO-1 Loops-For Loop, Opto Isolation need Interface Buses-USB,PXI Modeling of level process Spectrum Analyzer
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 101
SLO-2 While Loop Performing analog input and analog output VXI, Basic control of level process in LabVIEW Waveform Generator
S-6 SLO-1 Arrays, Scanning multiple analog channels SCXI Modeling of Reactor Processes
Data visualization from multiple locations
SLO-2 Clusters, plotting data Issues involved in selection of Data acquisition cards
PCMCIA Basic control of Reactor process in LabVIEW
Distributed monitoring and control
S-7 SLO-1
Lab-5: Program to find Addition of First n natural numbers using for loop
Lab-14: Flow measurement in water using LabVEW and DAQ hardware
Lab-18: DC motor control using VXI Lab-24: On-off Level controller using LabVIEW
Lab-30: Real time spectrum analysis using LabVIEW
SLO-2 Lab-6: Program to find Addition of First n odd numbers using while loop.
S-8 SLO-1
Lab-7: Implementation of Array functions. Lab-19: GPIB with VISA functions
Lab-25: Continuous Control of pressure controller using LabVIEW
Lab-31: Arbitratory Waveform Generator using LabVIEW
SLO-2 Lab-8: Calculation of BMI using cluster
S-9 SLO-1 Charts
Data acquisition modules with serial communication
Instrumentation Buses - Modbus and GPIB
Case studies on development of HMI in VI Vision and Motion Control
SLO-2 Graphs Design of digital voltmeters with transducer input
Networked busses – ISO/OSI Case studies on development of HMI in VI Examples on Integrating Measurement with vision and motion
S-10 SLO-1 Case and Sequence Structures Timers and Counters Reference model,
Case studies on development of SCADA in VI NI Motion control
SLO-2 Formula nodes, String and File Input/Output.
Timers and Counters Ethernet and TCP / IP Protocols Case studies on development of SCADA in VI Speed control system
S-11 SLO-1
Lab-9: Monitoring of temperature using Charts and Graphs Lab-15: Design of digital voltmeters with
transducer input using LabVIEW Lab-20: Online temperature control using LabVIEW using TCP/IP
Lab-26: On-off pressure controller using LabVIEW
Lab-32: Minor Project SLO-2 Lab-10: Program for implementing Seven segment display
S-12 SLO-1 Lab-11: Program to perform Traffic light
control Lab-16: Pressure measurement using LabVEW and DAQ hardware DAQ.
Lab-21: Online temperature control using Web publishing tool
Lab-27: Continuous Control of pressure controller using LabVIEW SLO-2
Learning Resources
1. Nadovich, C., Synthetic Instruments Concepts and Applications, Elsevier, 2005 2. Bitter, R., Mohiuddin, T. and Nawrocki, M., Labview Advanced Programming Techniques, 2nd ed., CRC Press, 2007 3. Gupta, S. and Gupta, J. P., PC Interfacing for Data Acquisition and Process Control”, 2nd ed., Instrument Society of
America, 1994
4. Jamal, R., Picklik, H., Labview – Applications and Solutions, National Instruments Release. 5. Johnson, G., Labview Graphical programming, McGraw-Hill, 1997 6. Wells, L.K., Travis, J., Labview for Everyone, Prentice Hall, 1997 7. Buchanan, W., Computer Busses, CRC Press, 2000
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)#
Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
20% 20% 15% 15% 15% 15% 15% 15% 15% 15% Understand
Level 2 Apply
20% 20% 20% 20% 20% 20% 20% 20% 20% 20% Analyze
Level 3 Evaluate
10% 10% 15% 15% 15% 15% 15% 15% 15% 15% Create
Total 100 % 100 % 100 % 100 % 100 %
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers
Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. D. Karthikeyan, Controlsoft Engineering India Pvt Ltd, [email protected] 1. Dr. J. Prakash, MIT, Chennai, [email protected] 1. Dr. K. A. Sunitha, SRMIST
2. V. Venkateswaran, Instrumentation Consultant, [email protected] 2. Dr. D. Nedumaran, Madras University, [email protected] 2. Mrs. A. Brindha, SRMIST
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 102
Course Code
18ECO132T Course Name
ANALYTICAL INSTRUMENTATION Course
Category O Open Elective
L T P C
3 0 0 3
Pre-requisite Courses
Nil Co-requisite
Courses Nil
Progressive Courses
Nil
Course Offering Department Electronics and Communication Engineering Data Book / Codes/Standards Nil
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Understand the principle and theory of analytical instruments 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
CLR-2 : Understand the quantitative analysis of dissolved components
Leve
l of T
hink
ing
(Blo
om)
Exp
ecte
d P
rofic
ienc
y (%
)
Exp
ecte
d A
ttain
men
t (%
)
Eng
inee
ring
Kno
wle
dge
Pro
blem
Ana
lysi
s
Des
ign
& D
evel
opm
ent
Ana
lysi
s, D
esig
n, R
esea
rch
Mod
ern
Too
l Usa
ge
Soc
iety
& C
ultu
re
Env
ironm
ent &
Sus
tain
abili
ty
Eth
ics
Indi
vidu
al &
Tea
m W
ork
Com
mun
icat
ion
Pro
ject
Mgt
. & F
inan
ce
Life
Lon
g Le
arni
ng
PS
O 1
: Aut
omat
ic c
ontr
ol f
or
cont
inou
s &
dis
cret
e sy
stem
s P
SO
-2: U
tiliz
e P
LC &
DC
S fo
r co
ntro
l of s
yste
ms
PS
O-3
: Effe
ctiv
e m
anag
emen
t
skill
s
CLR-3 : Study the concept of separation science and its applications
CLR-4 : Study the various spectroscopic techniques and its instrumentation
CLR-5 : Identify and solve engineering problems associated with Radiation Techniques CLR-6 : Understand the working of Analytical Instrument and their importance in industries
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Apply the principles and theory of instrumental analysis 1,2 80 70 H H L L H H H H H L
CLO-2 : Apply the principles of various chemical analysis instruments in industries 1,2 85 75 H H L L H H H H L CLO-3 : Analyze and understand the operation of various radio chemical methods of analysis 1,2 75 70 H H L L H H H H L
CLO-4 : To analyze and understand the operation of instruments based on optical properties 1,2 85 80 H H L L H H H H L
CLO-5 : To identify and solve engineering problems associated with Radiation Techniques 1,2 85 75 H H L L H H H H L
CLO-6 : To understand the working of analytical Instruments in industries 1,2 80 70 H H L L H H H H L
Duration (hour) Learning Unit / Module 1 Learning Unit / Module 2 Learning Unit / Module 3 Learning Unit / Module 4 Learning Unit / Module 5
9 9 9 9 9
S-1 SLO-1
Introduction to Chemical instrumental analysis
Dissolved oxygen analyzer, Importance of measuring dissolved oxygen in Industry, Principle working
Chromatography, Importance, Basic working of Chromatography
Spectral methods of analysis- Properties or parameters of electromagnetic radiation
NMR spectrometers ,Importance and basic working of NMR Spectroscopy
SLO-2 Spectral method of analysis
Working of Dissolved oxygen analyzer Gas chromatography Instrumentation
Electromagnetic spectrum Types of spectrometers
Magnetic assembly, Probe unit, Instrument stabilization
S-2 SLO-1
Electro analytical and seperative methods
sodium analyzer, Importance of measuring sodium in Industry, Principle working
Basic parts of a gas chromatography Beer's law UV-visible spectrophotometers Transmittance and absorbance
Types of NMR spectrometer, Minimal type
SLO-2 Instrumental methods of analysis-basic components and their classification
Working of sodium analyzer Carrier gas supply Sample injection system
Beer’s law Application of beer’s law
Multipurpose NMR,Wideline
S-3 SLO-1 Sampling systems
Silica analyzer, Importance of measuring Silica in Industry, Principle working
Chromatographic column, Selection of column
Derivations of beer’s law Applications of NMR Spectrometer
SLO-2 Importance of Sampling system in chemical Industries and Safety aspects
Working of Silica Analyzer Thermal compartment, Detection system, Recording system
Single beam and double beam instruments Mass Spectrometers, Basic working and Importance
S-4
SLO-1 PH Measurement, Principle of PH measurement & Importance of PH measurement in Industries
Moisture measurement Importance of Moisture measurement
Liquid chromatography-Principles, types and applications
IR spectrophotometers Instruments of IR
Components of Mass Spectrometers
SLO-2 Types of Electrodes, Reference Electrodes and types
Types of Moisture measurement High pressure liquid chromatography Types of IR Components required for three types of IR
Types of Mass spectrometers Magnetic Sector analyzer, Double focusing spectrometers
S-5 SLO-1 Secondary Electrodes and Types Oxygen analyzer Methods of oxygen analyzers and importance
Instrumentation or basic component of HPLC
Instruments of dispersive instrument , IR Radiation Sources and types
Time of flight analyzers, Quadrupole Mass analyzers
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 103
SLO-2 Indicator electrodes Paramagnetic oxygen analyzer Electro analytical method
Solvent reservoir and its treatment system
Importance of Monochromators and types of Monochromators
Application of mass spectrophotometers
S-6
SLO-1 pH meters direct reading type pH meter null detector type pH meter
CO monitor,Importance of measuring CO Pumping system, Types of working systems and Importance
Samples And Sample Cells detectors
nuclear radiation detectors, importance of measurement
SLO-2
ion selective electrodes Types of ion selective electrodes Glass membrane electrodes Liquid membrane electrodes Solid membrane Electrodes
Types of CO monitor Pulse dampers FTIR spectrometers, Main components Advantages, disadvantages
GM counter
S-7 SLO-1
Biosensors Features of Biosensor Block diagram of bio sensor
NO2 analyzer, Importance of NO2
measurement
Sample injection system and types
Types of sources Selection factors
Working setup, advantages of GM Counter
SLO-2 Applications of Biosensors in industries Types of NO2 measurement Liquid chromatographic column working , Types of Column thermostats
Types of detectors Selection factors
proportional counter, Basic Principle
S-8 SLO-1
conductivity meters ,Importance in Chemical Industries
H2S analyzer, Importance of H2 S Measurement
Detection system types atomic absorption spectrophotometer instruments for atomic absorption spectroscopy
Working setup, advantages of GM Counter
SLO-2 Types of Conductivity meters Types of H2S measurement Types of Recording system radiation source chopper
solid state detectors, Basic Principle
S-9
SLO-1 Air pollution Monitoring Instruments Dust and smoke measurement- dust measurement and Importance Types of dust measurement
Application of HPLC, Advantages of HPLC over gas chromatography
production of atomic vapor by flame, Parts by flame photometer Emission system
Working setup, advantages of Solid state detectors
SLO-2 Estimation of Air pollution Thermal analyzer , Importance of Thermal analyzers, Types of Thermal analyzer
Detectors types, Factors Influencing the Selection of Detectors
Monochromators And types, Types of Detectors and recording systems and their selection criteria
scintillation counter, Basic principle
Learning Resources
1. Khandpur. R.S, “Handbook of Analytical Instruments”, Tata McGraw Hill publishing Co. Ltd., 2006 2. Bella. G, Liptak, “Process Measurement and analysis”., CRC press LLC.,2003. 3. Francis Rousseau and Annick Rouesssac “Chemical analysis Modern Instrumentation Methods and
Techniques”, John wiley & sons Ltd.2007.
4. James W.Robinson,“Undergraduate Instrumental Analysis”, Marcel Dekker., 2005. 5. Dwayne Heard, “Analytical Techniques for atmospheric measurement”, Blackwell Publishing,
2006.
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)#
Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
40 % - 30 % - 30 % - 30 % - 30% - Understand
Level 2 Apply
40 % - 40 % - 40 % - 40 % - 40% - Analyze
Level 3 Evaluate
20 % - 30 % - 30 % - 30 % - 30% - Create
Total 100 % 100 % 100 % 100 % 100 %
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers
Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. D. Karthikeyan, Controlsoft Engineering India Pvt Ltd, [email protected] 1. Dr. J. Prakash, MIT, Chennai, [email protected] Dr. K. A. Sunitha, SRMIST
2. V. Venkateswaran, Instrumentation Consultant, [email protected] 2. Dr. D. Nedumaran, Madras University, [email protected] Mrs. A. Brindha, SRMIST
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 104
Course Code 18ECO133T Course Name SENSORS AND TRANSDUCERS Course
Category O Open Elective
L T P C
3 0 0 3
Pre-requisite Courses
Nil Co-requisite
Courses Nil
Progressive Courses
Nil
Course Offering Department Electronics and Instrumentation Engineering Data Book / Codes/Standards Nil
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Gain knowledge on classification, and characteristics of transducers 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
CLR-2 : Acquire the knowledge of different types of inductive and capacitive sensors
Leve
l of T
hink
ing
(Blo
om)
Exp
ecte
d P
rofic
ienc
y (%
)
Exp
ecte
d A
ttain
men
t (%
)
Eng
inee
ring
Kno
wle
dge
Pro
blem
Ana
lysi
s
Des
ign
& D
evel
opm
ent
Ana
lysi
s, D
esig
n, R
esea
rch
Mod
ern
Too
l Usa
ge
Soc
iety
& C
ultu
re
Env
ironm
ent &
Sus
tain
abili
ty
Eth
ics
Indi
vidu
al &
Tea
m W
ork
Com
mun
icat
ion
Pro
ject
Mgt
. & F
inan
ce
Life
Lon
g Le
arni
ng
PS
O 1
: Aut
omat
ic c
ontr
ol f
or
cont
inuo
us&
dis
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s
PS
O-2
: Util
ize
PLC
& D
CS
for
cont
rol o
f sys
tem
s
PS
O-3
: Effe
ctiv
e m
anag
emen
t
skill
s
CLR-3 : Acquire the knowledge of different types of thermal and radiation sensors
CLR-4 : Acquire the knowledge of different types of magnetic sensors
CLR-5 : Acquire the knowledgeof different types of sensors measuring non-Electrical quantity
CLR-6 : Locate the Applications of sensors in industries and home appliances
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : To demonstrate the various types of basic sensors. 2,3 80 80 H - H - - H H H - - - H H - -
CLO-2 : Understand the inductive and capacitive sensors which are used for measuring various parameters.
1,2 80 80 H - - H - H - - - - - H - H -
CLO-3 : Understand the thermal and radiation sensors 1 80 80 - - - - - H - - H H - - H - -
CLO-4 : Have an adequate knowledge on the various magnetic sensors 3 80 80 - H H - - - - - - - - - - H -
CLO-5 : To demonstrate the various types of basic sensors measuring non electrical quantity 3 80 80
- - H - H - - - - - - H - - H
CLO-6 : Select the right transducer for the given application 3 80 80 H - H - - H H H - - - H H - -
Duration (hour) 9 9 9 9 9
S-1 SLO-1
Introduction to sensors/ transducers, Principles
Introduction to Inductive sensor Thermal sensors: Introduction Magnetic sensors: Introduction Measurement of Non-Electrical quantity: Introduction
SLO-2 Classification based on different criteria Sensitivity and linearity of the sensor Thermal Expansion type. Villari effect Flow Measurement – Introduction.
S-2 SLO-1 Characteristics of measurement systems Transformer type transducer Acoustics temperature sensors. Wiedmann effect Ultrasonic Flow Meters.
SLO-2 Static characteristics Accuracy, Precision, Resolution, Sensitivity
Electromagnetic transducer Thermo-emf sensor. Hall effect Hot Wire Anemometers.
S-3 SLO-1 Dynamic characteristics. Magnetosrtictive transducer Materials for thermos-emf sensors. Construction, Electromagnetic Flow meters.
SLO-2 Environmental Parameters Materials used in inductive sensor Thermocouple construction performance characteristics, Principle and types.
S-4 SLO-1 Characterization and its type Mutual Inductance change type Types. and its Application Measurement of Displacement.
SLO-2 Electrical characterization. LVDT: Construction. Thermo-sensors using semiconductor device
Introduction to smart sensors Introduction and types.
S-5 SLO-1 Mechanical Characterization. Material, input output relationship, Pyroelectric thermal sensors Film sensors: Introduction Measurement of Velocity/ Speed.
SLO-2 Thermal Characterization Synchros-Construction Introduction Thick film sensors Introduction and types.
S-6 SLO-1 Optical Characterization. Capacitive sensor: Introduction characteristics Microelectromechanical systems Measurement of Liquid Level.
SLO-2 Errors and its classification. Parallel plate capacitive sensor Application Micromachining. Introduction and types.
S-7 SLO-1 Selection of transducers. Variable thickness dielectric capacitive sensor
Radiation sensors. Nano sensors Measurement of Pressure.
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 105
SLO-2 Introduction to mechanical sensors Electrostatic transducer Introduction Applications: Industrial weighing systems: Link–lever mechanism.
Introduction and types.
S-8 SLO-1 Resistive potentiometer and types Piezoelectric elements Characteristics
Load cells – pneumatic, elastic and their mounting.
Measurement of Vibration.
SLO-2 Strain gauge: Theory, type, design consideration, sensitivity.
Ultrasonic Sensors Geiger counters different designs of weighing systems. Introduction and types.
S-9 SLO-1
Resistive transducer: RTD, materials used in RTD
Calculation of sensitivity. Scintillation detectors conveyors type. Application of sensors in industries
SLO-2 Thermistor: thermistor material, shape Capacitor microphone, response characteristics
Application on radiation sensors weighfeeder type. Application of sensors in home appliances
Learning Resources
1. Patranabis, D., “Sensors and Transducers”, 2nd Edition, Prentice Hall India Pvt. Ltd, 2010. 2. Doeblin, E.O., “Measurement Systems: Applications and Design”, 6thEdition, Tata McGraw-Hill
Book Co., 2011. 3. Bentley, J. P., “Principles of Measurement Systems”, 4th Edition, Addison Wesley Longman Ltd.,
UK, 2004.
4. Murthy, D.V.S., “Transducers and Instrumentation”, Prentice Hall of India Pvt. Ltd., New Delhi, 2010. 5. Neubert H.K.P., “Instrument Transducers – An Introduction to their performance and Design”, Oxford
University Press, Cambridge, 2003.
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)# Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
40 % - 30 % - 30 % - 30 % - 30% - Understand
Level 2 Apply
40 % - 40 % - 40 % - 40 % - 40% - Analyze
Level 3 Evaluate
20 % - 30 % - 30 % - 30 % - 30% - Create
Total 100 % 100 % 100 % 100 % 100 %
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers
Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. D. Karthikeyan, Controlsoft Engineering India Pvt Ltd, [email protected] 1. Dr. J. Prakash, MIT, Chennai, [email protected] Mrs. K. Vibha, SRMIST
2. V. Venkateswaran, Instrumentation Consultant, [email protected] 2. Dr. D. Nedumaran, Madras University, [email protected] Dr. G. Joselin Retna Kumar, SRMIST
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 106
Course Code
18ECO134T Course Name
INDUSTRIAL AUTOMATION Course
Category O Open Elective
L T P C
3 0 0 3
Pre-requisite Courses
Nil Co-requisite
Courses Nil
Progressive Courses
Nil
Course Offering Department Electronics and Communication Data Book / Codes/Standards Nil
Course Learning Rationale (CLR): The purpose of learning this course is to: Learning Program Learning Outcomes (PLO)
CLR-1 : Understand basic components of PLC 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
CLR-2 : Understand the use of timers and counters in process automation
Leve
l of T
hink
ing
(Blo
om)
Exp
ecte
d P
rofic
ienc
y (%
)
Exp
ecte
d A
ttain
men
t (%
)
Eng
inee
ring
Kno
wle
dge
Pro
blem
Ana
lysi
s
Des
ign
& D
evel
opm
ent
Ana
lysi
s, D
esig
n, R
esea
rch
Mod
ern
Too
l Usa
ge
Soc
iety
& C
ultu
re
Env
ironm
ent &
Sus
tain
abili
ty
Eth
ics
Indi
vidu
al &
Tea
m W
ork
Com
mun
icat
ion
Pro
ject
Mgt
. & F
inan
ce
Life
Lon
g Le
arni
ng
PS
O 1
: Aut
omat
ic c
ontr
ol f
or
cont
inou
s &
dis
cret
e sy
stem
s P
SO
-2: U
tiliz
e P
LC &
DC
S fo
r co
ntro
l of s
yste
ms
PS
O-3
: Effe
ctiv
e m
anag
emen
t
skill
s
CLR-3 : Understand DCS architecture
CLR-4 : Understand operator and engineering interface in DCS
CLR-5 : Understand HART signal standard and Field bus CLR-6 : Understand Field bus signal standard.
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Select PLC based on I/O’s 2,3 80 80 H M L - - - - - M - M L M M
CLO-2 : Apply timers and counters in process automation 1,2 80 80 H H H H H - L - H M L L H H H CLO-3 : Select LCU based on application 1 80 80 H M - - - - - - L - - L M L M
CLO-4 : Analyse data’s in Operator displays 3 80 80 H H - H - - - - H M - L H L M
CLO-5 : Interpret industrial data communication modes 3 80 80 H - - - - - - - - L - L H - L
CLO-6 : Gain knowledge on field bus 3 80 80 H L - - - - - - - - - L H - L
Duration (hour) 9 9 9 9 9
S-1
SLO-1 Programmable logic controllers PLC Programming Languages Evolution of DCS Operator Interfaces Requirements Introduction to HART
SLO-2 PLC vs Computer Ladder Diagram Hybrid System Architecture
Process Monitoring Evolution of Signal standard
S-2 SLO-1 Parts of a PLC Functional block Central Computer system Architecture
Process Control HART Networks: Point-to-Point
SLO-2 Architecture Sequential Function Chart DCS Architecture Process Diagnostics Multi-drop
S-3 SLO-1 PLC size and Application. Instruction List Comparison of Architecture Process Record Keeping Split range control valve
SLO-2 Fixed and Modular I/O Structured Text Local Control Unit Architecture Low Level Operator Interface HART Field Controller Implementation
S-4 SLO-1 Discrete Input Modules Wiring Diagram Architectural Parameters High Level Operator Interface Hart Commends: Universal
SLO-2 Discrete Output Modules Ladder logic Program Comparison Of LCU Architecture Hardware Elements In The Operator
Interface Common Practice
S-5 SLO-1 Analog Input Modules On-Delay Timer Instruction LCU Language Requirements Operator Input And Output Devices Device Specific
SLO-2 Analog Output Modules Off-Delay Timer Instruction Function Blocks Operator Display Hierarchy Wireless Hart
S-6 SLO-1 Special I/O Modules Retentive Timer Function Block Libraries Plant-Level Display Field Bus Basics
SLO-2 High Speed Counter Module Cascading Timer Problem-Oriented Language Area- Level Display Field Bus Architecture
S-7 SLO-1 Power Supplies Up-Counter LCU Process Interfacing Issues Group- Level Display Field Bus Standard
SLO-2 Isolators Down-Counter Security Requirements Loop- Level Display Field Bus Topology
S-8 SLO-1 Input/output Devices: Switches Cascading Counters Security Design Approach Engineering Interface Requirements H1 Field Bus
SLO-2 sensors Combining Counter And Timer Functions On-Line Diagnostics Requirement For Operator Interface
Configuration H2 Field Bus
S-9 SLO-1 Relays Math Operation Redundant Controller Design Low Level Engineering Interface, Interoperability
SLO-2 Solenoid valve Program One-On-One, One-On-Many Redundancy High Level Engineering Interfaces Interchangeability
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 107
Learning Resources
1. Frank D. Petruzella, Programmable Logic Controller, Tata McGraw Hill Fifth Edition, 2017 2. Bolton. W, Programmable Logic Controllers, 6th Edition, Elsevier Newnes, Sixth Edition 2016. 3. Krishna Kant, Computer Based Industrial Control, Second edition, Prentice Hall of India, New Delhi,2015
4. Bowten, R HART Application Guide, HART Communication foundation, 2015. 5. Berge, J, Field Busses for process control: Engineering, operation, maintenance, ISA press,2015
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)#
Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
40 % - 30 % - 30 % - 30 % - 30% - Understand
Level 2 Apply
40 % - 40 % - 40 % - 40 % - 40% - Analyze
Level 3 Evaluate
20 % - 30 % - 30 % - 30 % - 30% - Create
Total 100 % 100 % 100 % 100 % 100 % # CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers
Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. D. Karthikeyan, Controlsoft Engineering India Pvt Ltd, [email protected] 1. Dr. J. Prakash, MIT, Chennai, [email protected] Mr. J. Sam Jeba Kumar, SRMIST
2. V. Venkateswaran, Instrumentation Consultant, [email protected] 2. Dr. D. Nedumaran, Madras University, [email protected] Dr. G. Joselin Retna Kumar, SRMIST
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 108
Course Code
18ECO135T Course Name
FUNDAMENTALS OF MEMS Course
Category O Open Elective
L T P C
3 0 0 3
Pre-requisite Courses
Nil Co-requisite
Courses Nil
Progressive Courses
Nil
Course Offering Department Electronics and Communication Engineering Data Book / Codes/Standards Nil
Course Learning Rationale (CLR): The purpose of learning this course is to:
Learning
Program Learning Outcomes (PLO)
CLR-1 : Understand the importance of micro system technology 1 2 3 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15
CLR-2 : Learn the operating principle of various micro sensors and actuators
Leve
l of T
hink
ing
(Blo
om)
Exp
ecte
d P
rofic
ienc
y (%
)
Exp
ecte
d A
ttain
men
t (%
)
Eng
inee
ring
Kno
wle
dge
Pro
blem
Ana
lysi
s
Des
ign
& D
evel
opm
ent
Ana
lysi
s, D
esig
n, R
esea
rch
Mod
ern
Too
l Usa
ge
Soc
iety
& C
ultu
re
Env
ironm
ent &
Sus
tain
abili
ty
Eth
ics
Indi
vidu
al &
Tea
m W
ork
Com
mun
icat
ion
Pro
ject
Mgt
. & F
inan
ce
Life
Lon
g Le
arni
ng
PS
O 1
: Aut
omat
ic c
ontr
ol f
or
cont
inuo
us&
dis
cret
e sy
stem
s P
SO
-2: U
tiliz
e P
LC &
DC
S fo
r co
ntro
l of s
yste
ms
PS
O-3
: Effe
ctiv
e m
anag
emen
t
skill
s
CLR-3 : Impart the applications of various micro fabrication techniques
CLR-4 : Understand the differences and need for microfabrication CLR-5 : Operate MEMS design tools to design simple micro devices
CLR-6 : Understand recent developments and challenges in MEMS
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Appreciate the fundamental concepts in MEMS technology 2,3 80% 80% H - - - - H - - - - - H H - H CLO-2 : Understand the fabrication and machining techniques of MEMS devices 1,2 80% 80% H - - - - H - - - - - H - - H
CLO-3 : Familiarize with the concepts of packaging of MEMS devices 1 80% 80% H - - H - H - - - - - H H - H
CLO-4 : Appreciate the significance of micro fabrication processes 3 80% 80% H - - H - - - - - - - H - - H
CLO-5 : Design and Simulate simple structures using MEMS software 3 80% 80% H - H H H - - H H - - H H - H
CLO-6 : Analyze recent trends and developments in MEMS technology 3 80% 80% H - - H - - - - - - - H H - H
Duration (hour)
Introduction Fabrication overview Micromachining Bonding & Sealing Recent trends
9 9 9 9 9
S-1 SLO-1
Introduction to MEMS and Brief recap of Macro devices
Introduction to Micro fabrication process Introduction of micro machining(MMC) process
Introduction to MEMS packaging Introduction to design tools and simulation
SLO-2 Microelectronics and Micro systems Significance of each technique Significance of MMC Challenges in packaging FEM analysis
S-2 SLO-1 Scaling laws in geometry Process Description of Photolithography Bulk MMC process – merits and demerits Different levels of Packaging
Design of a silicon die for a micro pressure sensor
SLO-2 Silicon as ideal material and as substrate Implementation of Photolithography Sequence of steps Die, device and system level Simulation in software
S-3 SLO-1 Si wafer production Process Description of CVD Significance of Isotropic etching
Differences in IC packaging technology And MEMS packaging
Application of MEMS in automotive industry
SLO-2 Cz process Implementation, merits and demerits of CVD
Anisotropic etching Airbag deployment
S-4 SLO-1
Sequential steps in wafer processing Process Description of PVD
Surface MMC process
Die Preparation Optical MEMS Application
SLO-2 Implementation, merits and demerits of PVD
Sequence of steps Plastic encapsulation and its significance Micro mirrors
S-5 SLO-1
Chemical and mechanical properties of Si and compounds
Process Description, implementation of Ion implantation
Challenges in surface MMC Types of wire bonding Thermo compression type
Micro fluidics Application
SLO-2 Chemical and mechanical properties of Polymers, Quartz and GaAs
Oxidation process Interfacial & Residual stresses Thermo sonic, Ultra sonic type Lab on chip module
S-6 SLO-1 Chemical, Biomedical type Micro sensors
Diffusion process LIGA process- description merits and demerits
Types of surface bonding – Adhesive IR and Gas sensing
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 109
SLO-2 Piezoelectric type of Micro sensors Wet etching methods Implementation soldering, SOI type of bonding Thermal sensors
S-7 SLO-1 Thermal, SMA, Piezoelectric actuators Properties of etchants
Process Design-block diagram and description
Anodic bonding and lift off process Micro power generation
SLO-2 Electro static type Micro Actuators Dry etching methods Electro-mechanical design, Thermo-electric design
Precautions to be taken Micro TEG
S-8 SLO-1
Micro devices- operation of Micro gears and micromotors
Production of plasma CAD- block diagram description and implementation
Types of sealing- Micro shells, Hermetic sealing
Chemical sensors
SLO-2 Micro devices –operation of Micro valves and pumps
Etch stop methods Micro ‘O’ rings,Reactive seal Micro humidity sensors
S-9 SLO-1
Case study Case study Case study Selection of packaging materials Micro pressure sensors
SLO-2 Material requirements Paper MEMS
Learning Resources
1. Tai-Ran Hsu, “MEMS and MICROSYSTEMS”, 22nd reprint edition, Wiley & sons, 2015 2. M. Madou, “Fundamentals of Micro fabrication”, Taylor and Francis group, 2002
3. VardhanGardener,”Micro sensors and smart devices”, John Wiley & Sons,2001 4. NPTEL link: https://nptel.ac.in/downloads/112108092/
Learning Assessment
Bloom’s
Level of Thinking
Continuous Learning Assessment (50% weightage) Final Examination (50% weightage)
CLA – 1 (10%) CLA – 2 (15%) CLA – 3 (15%) CLA – 4 (10%)# Theory Practice Theory Practice Theory Practice Theory Practice Theory Practice
Level 1 Remember
30 % - 30 % - 30 % - 30 % - 30% - Understand
Level 2 Apply
40 % - 40 % - 40 % - 40 % - 40% - Analyze
Level 3 Evaluate
30 % - 30 % - 30 % - 30 % - 30% - Create
Total 100 % 100 % 100 % 100 % 100 %
# CLA – 4 can be from any combination of these: Assignments, Seminars, Tech Talks, Mini-Projects, Case-Studies, Self-Study, MOOCs, Certifications, Conf. Paper etc.,
Course Designers
Experts from Industry Experts from Higher Technical Institutions Internal Experts
1. D. Karthikeyan, Controlsoft Engineering India Pvt Ltd, [email protected] 1. Dr. J. Prakash, MIT, Chennai, [email protected] 1. Dr. A. Vimala Juliet, SRMIST
2. Mr. Hariharasudhan - Johnson Controls, Pune, [email protected] 2. Dr. D. Nedumaran, Madras University, [email protected] 2. R.Bakiyalakshmi,SRMIST
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 110
B. Tech in Electronics and Communication Engineering (with specialization in Cyber Physical System)
2018 Regulations
Project Work, Seminar, Internship in Industry / Higher Technical Institutions (P)
Department of Electronics and Communication Engineering SRM Institute of Science and Technology
SRM Nagar, Kattankulathur – 603203, Kancheepuram District, Tamilnadu
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 111
Course Code
18ECP109L / 18ECP110L
Course Name
PROJECT / SEMESTER INTERNSHIP Course
Category
P
Project Work, Seminar, Internship In Industry / Higher Technical Institutions (P)
L T P C
0 0 20 10
Pre-requisite Courses
Nil Co-requisite
Courses Nil
Progressive Courses
Nil
Course Offering Department Electronics and Communication Engineering Data Book / Codes/Standards As required for the project work
Course Learning Rationale (CLR): The purpose of learning this course is to:
CLR-1 : To prepare the student to gain major design and or research experience as applicable to the profession
CLR-2 : Apply knowledge and skills acquired through earlier course work in the chosen project
CLR-3 : Make conversant with the codes, standards , application software and equipment
CLR-4 : Carry out the projects within multiple design constraints
CLR-5 : Incorporate multidisciplinary components
CLR-6: Acquire the skills of comprehensive report writing
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Design a system / process or gain research insight into a defined problem as would be encountered in engineering practice taking into consideration its impact on global, economic, environmental and social context.
Learning Assessment
Continuous Learning Assessment
Assessment tool Review I Review II Review III Total
Weightage 5% 20% 25% 50%
Final Evaluation Assessment tool Project Report Viva Voce * Total
Weightage 20% 30% 50%
* Student has to be present for the viva voce for assessment. Otherwise it will be treated as non-appearance for the examination with final grade as ‘Ab’
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 112
Course Code
18ECP107L Course Name
MINOR PROJECT Course
Category
P
Project Work, Seminar, Internship In Industry / Higher Technical Institutions (P)
L T P C
0 0 6 3
Pre-requisite Courses
Nil Co-requisite
Courses Nil
Progressive Courses
Nil
Course Offering Department Electronics and Communication Engineering Data Book / Codes/Standards As required for the project work
Course Learning Rationale (CLR): The purpose of learning this course is to:
CLR-1 : Prepare the student to formulate an engineering problem within the domain of the courses undergone
CLR-2 : Seek solution to the problem by applying codes / standards/ software or carrying out experiments or through programming
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Identify a small part of major system or process, understand a problem associated with it and find solution or suggest a procedure leading to its solution.
Learning Assessment
Continuous Learning Assessment
Assessment tool Review I Review II Final Review * Total
Weightage 20% 30% 50% 100%
* Student has to be present for final review for assessment. Otherwise it will be treated as non-appearance for the examination with final grade as ‘Ab’
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 113
Course Code
18ECP101L / 18ECP104L
Course Name
MASSIVE OPEN ONLINE COURSE I / II Course
Category
P
Project Work, Seminar, Internship In Industry / Higher Technical Institutions (P)
L T P C
0 0 2 1
Pre-requisite Courses
Nil Co-requisite
Courses Nil
Progressive Courses
Nil
Course Offering Department Electronics and Communication Engineering Data Book / Codes/Standards As exposed to during the duration of training
Course Learning Rationale (CLR): The purpose of learning this course is to:
CLR-1 :
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Apply the concepts, theories, laws, technologies learnt herein to provide engineering solutions.
CLO-2 : Engage in independent and life-long learning
CLO-3 : Solve the real world problems individually and in collaboration
Learning Assessment
In-semester Assessment tool Quiz Assignment Non-proctored / Unsupervised Tests Proctored / Supervised Test Total
Weightage 25% 25% 10% 40% 100%
End semester examination Weightage : 0%
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 114
Course Code
18ECP102L / 18ECP105L
Course Name
INDUSTRIAL TRAINING I / II Course
Category
P
Project Work, Seminar, Internship In Industry / Higher Technical Institutions (P)
L T P C
0 0 2 1
Pre-requisite Courses
Nil Co-requisite
Courses Nil
Progressive Courses
Nil
Course Offering Department Electronics and Communication Engineering Data Book / Codes/Standards As exposed to during the duration of training
Course Learning Rationale (CLR): The purpose of learning this course is to:
CLR-1 : Provide an exposure to the students on the practical application of theoretical concepts in an industry or research institute
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Gain confidence to carry out supervisory, managerial, and design roles in an industrial context.
Learning Assessment
Continuous Learning Assessment
Assessment tool Final review
Weightage Training Report Presentation *
75% 25%
* Student has to be present for the presentation for assessment. Otherwise it will be treated as non-appearance for the examination with final grade as ‘Ab’
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 115
Course Code
18ECP108L Course Name
INTERNSHIP Course
Category P
Project Work, Seminar, Internship In Industry / Higher Technical Institutions (P)
L T P C
0 0 6 3
Pre-requisite Courses
Nil Co-requisite
Courses Nil
Progressive Courses
Nil
Course Offering Department Electronics and Communication Engineering Data Book / Codes/Standards As exposed to during the duration of internship
Course Learning Rationale (CLR): The purpose of learning this course is to:
CLR-1 : Provide an exposure to the students on the practical application of theoretical concepts in an industry or research institute and also to gain hands on experience in the context of design, production and maintenance
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Gain confidence to carry out supervisory, managerial, and design roles in an industrial context or research environment
Learning Assessment
Continuous Learning Assessment
Assessment tool Final review
Weightage Training Report Presentation*
75% 25%
* Student has to be present for the presentation for assessment. Otherwise it will be treated as non-appearance for the examination with final grade as ‘Ab’
B.Tech (ECE-CPS) SRM Institute of Science & Technology – Academic Curricula (2018 Regulations) 116
Course Code
18ECP103L / 18ECP106L
Course Name
SEMINAR I / II Course
Category P
Project Work, Seminar, Internship In Industry / Higher Technical Institutions (P)
L T P C
0 0 2 1
Pre-requisite
Courses Nil
Co-requisite Courses
Nil Progressive
Courses Nil
Course Offering Department Electronics and Communication Engineering Data Book / Codes/Standards As applicable
Course Learning Rationale (CLR): The purpose of learning this course is to:
CLR-1 : Identify an area of interest within the program or a related one (multidisciplinary), carry out a literature survey on it, gain understanding and present the same before an audience.
Course Learning Outcomes (CLO): At the end of this course, learners will be able to:
CLO-1 : Carry out a self-study of an area of interest and communicate the same to others with clarity.
Learning Assessment
Continuous Learning Assessment
Assessment tool Presentation
Weightage Presentation material
Presentation skills / ability to answer questions / understanding of the topic*
60% 40%
* Student has to be present for the presentation for assessment. Otherwise it will be treated as non-appearance for the examination with final grade as ‘Ab’